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Advanced Chemical Reaction Engineering (PG) |
Lecture 1 - Course Overview - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 2 - Course Overview - II |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 3 - Design Equations - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 4 - Design Equations - Illustrative Examples |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 5 - Design Equations - II : Plug Flow Recycle Reactors |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 6 - Illustrative Examples : 1) Plug Flow Recycle 2) Multiple reactions - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 7 - Illustrative Examples : 1) Recycle Reactor with Condenser 2) CSTR with Recycle |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 8 - Multiple Reactions - II |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 9 - Modelling Multiple Reactions in Soil Environment - III |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 10 - Semi Continuous Reactor Operation |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 11 - Catalyst Deactivation - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 12 - Catalyst Deactivation - II |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 13 - Illustrative Example : 1) Determination of deactivation Parameters 2) Design for Deactivating Catalyst |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 14 - Energy Balance - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 15 - Energy Balance - II |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 16 - Reacting Fluids as Energy Carrier |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 17 - Illustrative Example : Energy Balance in Stirred Vessels |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 18 - Energy Balance - III : Design for Constant T Operation |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 19 - Energy Balance - IV : Temperature Effects on Rate & Equilibria |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 20 - Energy Balance - V : Stability Analysis of Exothermic Stirred Tank |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 21 - Illustrative Example : Stability of Exothermic Stirred Tank |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 22 - Energy Balance - VI : 1) Tubular Reactor Heated/Cooled from Wall 2) Transient Behavior of CSTR |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 23 - Illustrative Example : 1) Plug Flow with Heat Effects 2) Multiple Reactions |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 24 - Illustrative Example : 1) Further Considerations in Energy Balance 2) Multiple Reactions |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 25 - Illustrative Example : 1) Hot Spot as Design Basis 2) Design for Instantaneous Reactions |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 26 - Residence Time Distribution Methods |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 27 - Residence Time Distribution Models |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 28 - Shrinking core Gas-Solid reactions Model |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 29 - Shrinking core Ash Diffusion Model & Combination of Resistances |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 30 - 1) Gas Solid Reactions Temperature Effects on Rate & Equilibria 2) Introduction to Population Balance - I |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 31 - Illustrative Example : Temperature Effects on Rate & Equilibria |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 32 - Population Balance Modelling - II |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 33 - Population Balance Modelling - III |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 34 - Illustrative Examples : Population Balance Models |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 35 - Introduction to Environmental Reactions |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 36 - Reaction Engineering Examples in Biochemical & Environmental Engineering |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 37 - Illustrative Examples : 1) Biomethanation 2) Alcohol via Fermentation 3) Natural Selection |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 38 - Illustrative Examples : 1) Enzyme Reaction 2) Microbial Reaction 3) Waste Treatment |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 39 - Oxygen Sag Analysis in Rivers |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 40 - Illustrative Examples : 1) Oxygen Sag Analysis 2) Population Balance Modelling of Forest 3) Sponge Iron Process |
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Advanced Chemical Reaction Engineering (PG) |
Lecture 41 - Illustrative Example : Gas- Solid Reaction RTD Models Reaction Network |
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Advanced Process Control |
Lecture 1 - Introduction and Motivation |
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Advanced Process Control |
Lecture 2 - Linearization of Mechanistic Models |
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Advanced Process Control |
Lecture 3 - Linearization of Mechanistic Models (Continued...) |
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Advanced Process Control |
Lecture 4 - Introduction to z-transforms and Development of Grey-box models |
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Advanced Process Control |
Lecture 5 - Introduction to Stability Analysis and Development of Output Error Models |
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Advanced Process Control |
Lecture 6 - Introduction to Stochastic Processes |
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Advanced Process Control |
Lecture 7 - Introduction to Stochastic Processes (Continued...) |
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Advanced Process Control |
Lecture 8 - Development of ARX models |
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Advanced Process Control |
Lecture 9 - Statistical Properties of ARX models and Development of ARMAX models |
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Advanced Process Control |
Lecture 10 - Development of ARMAX models (Continued...) and Issues in Model Development |
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Advanced Process Control |
Lecture 11 - Model Structure Selection and Issues in Model Development (Continued...) |
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Advanced Process Control |
Lecture 12 - Issues in Model Development (Continued...) and State Realizations of Transfer Function Models |
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Advanced Process Control |
Lecture 13 - Stability Analysis of Discrete Time Systems |
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Advanced Process Control |
Lecture 14 - Lyapunov Functions and Interaction Analysis and Multi-loop Control |
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Advanced Process Control |
Lecture 15 - Interaction Analysis and Multi-loop Control (Continued...) |
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Advanced Process Control |
Lecture 16 - Multivariable Decoupling Control and Soft Sensing and State Estimation |
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Advanced Process Control |
Lecture 17 - Development of Luenberger Observer |
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Advanced Process Control |
Lecture 18 - Development of Luenberger Observer (Continued...) and Introduction to Kalman Filtering |
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Advanced Process Control |
Lecture 19 - Kalman Filtering |
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Advanced Process Control |
Lecture 20 - Kalman Filtering (Continued...) |
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Advanced Process Control |
Lecture 21 - Kalman Filtering (Continued...) |
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Advanced Process Control |
Lecture 22 - Pole Placement State Feedback Control Design and Introduction to Linear Quadratic Gaussian (LQG) Control |
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Advanced Process Control |
Lecture 23 - Linear Quadratic Gaussian (LQG) Regulator Design |
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Advanced Process Control |
Lecture 24 - Linear Quadratic Gaussian (LQG) Controller Design |
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Advanced Process Control |
Lecture 25 - Model Predictive Control (MPC) |
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Advanced Process Control |
Lecture 26 - Model Predictive Control (Continued...) |
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Chemical Reaction Engineering II |
Lecture 1 - Introduction to catalysts and catalysis |
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Chemical Reaction Engineering II |
Lecture 2 - Steps in catalytic reaction: adsorption, desorption and reaction |
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Chemical Reaction Engineering II |
Lecture 3 - Derivation of the rate equation |
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Chemical Reaction Engineering II |
Lecture 4 - Heterogenous data analysis for reactor design - I |
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Chemical Reaction Engineering II |
Lecture 5 - Heterogenous data analysis for reactor design - II |
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Chemical Reaction Engineering II |
Lecture 6 - Catalyst deactivation and accounting for it in design - I |
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Chemical Reaction Engineering II |
Lecture 7 - Catalyst deactivation and accounting for it in design - II |
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Chemical Reaction Engineering II |
Lecture 8 - Synthesize the rate equation |
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Chemical Reaction Engineering II |
Lecture 9 - Introduction to intraparticle diffusion |
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Chemical Reaction Engineering II |
Lecture 10 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - I |
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Chemical Reaction Engineering II |
Lecture 11 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - II |
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Chemical Reaction Engineering II |
Lecture 12 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - III |
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Chemical Reaction Engineering II |
Lecture 13 - Effectiveness factor and Introduction to external mass transfer |
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Chemical Reaction Engineering II |
Lecture 14 - External Mass Transfer |
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Chemical Reaction Engineering II |
Lecture 15 - Implications to rate data interpretation and design - I |
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Chemical Reaction Engineering II |
Lecture 16 - Implications to rate data interpretation and design - II |
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Chemical Reaction Engineering II |
Lecture 17 - Packed-bed reactor design |
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Chemical Reaction Engineering II |
Lecture 18 - Fluidized bed reactor design - I |
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Chemical Reaction Engineering II |
Lecture 19 - Fluidized bed reactor design - II |
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Chemical Reaction Engineering II |
Lecture 20 - Gas-liquid reactions-1: Theories of mass transfer into agitated liquids |
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Chemical Reaction Engineering II |
Lecture 21 - GLR-2: Effect of chemical reaction on mass transfer: the slow reaction regime |
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Chemical Reaction Engineering II |
Lecture 22 - GLR-3: Transition to fast reaction, and the Fast reaction regime |
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Chemical Reaction Engineering II |
Lecture 23 - GLR-4: Fast reaction example; Instantaneous reaction regime |
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Chemical Reaction Engineering II |
Lecture 24 - GLR-5: Transition to Instantaneous reaction; Reaction regimes in surface renewal theories |
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Chemical Reaction Engineering II |
Lecture 25 - GLR-6: Reaction regimes in surface renewal theories (Continued..) |
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Chemical Reaction Engineering II |
Lecture 26 - GLR-7: Surface renewal theories: Instantaneous reaction and Summing up |
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Chemical Reaction Engineering II |
Lecture 27 - Fluid-solid non-catalytic reactions - I |
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Chemical Reaction Engineering II |
Lecture 28 - Fluid-solid non-catalytic reactions - II |
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Chemical Reaction Engineering II |
Lecture 29 - Fluid-solid non-catalytic reactions - III |
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Chemical Reaction Engineering II |
Lecture 30 - Distribution of residence time |
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Chemical Reaction Engineering II |
Lecture 31 - Measurement of residence time distribution |
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Chemical Reaction Engineering II |
Lecture 32 - Residence time distribution function |
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Chemical Reaction Engineering II |
Lecture 33 - Reactor diagnostics and troubleshooting |
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Chemical Reaction Engineering II |
Lecture 34 - Modeling non-ideal reactors |
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Chemical Reaction Engineering II |
Lecture 35 - Residence time distribution: Performance of non-ideal reactors |
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Chemical Reaction Engineering II |
Lecture 36 - Non-ideal Reactors: Tanks-in-series model |
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Chemical Reaction Engineering II |
Lecture 37 - Non-ideal Reactors: Dispersion model |
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Chemical Reaction Engineering II |
Lecture 38 - Non-ideal Reactors: Dispersion model and introduction to multiparameter models |
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Chemical Reaction Engineering II |
Lecture 39 - Non-ideal Reactors: Multiparameter models |
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Advanced Numerical Analysis |
Lecture 1 - Introduction and Overview |
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Advanced Numerical Analysis |
Lecture 2 - Fundamentals of Vector Spaces |
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Advanced Numerical Analysis |
Lecture 3 - Basic Dimension and Sub-space of a Vector Space |
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Advanced Numerical Analysis |
Lecture 4 - Introduction to Normed Vector Spaces |
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Advanced Numerical Analysis |
Lecture 5 - Examples of Norms,Cauchy Sequence and Convergence, Introduction to Banach Spaces |
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Advanced Numerical Analysis |
Lecture 6 - Introduction to Inner Product Spaces |
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Advanced Numerical Analysis |
Lecture 7 - Cauchy Schwaz Inequality and Orthogonal Sets |
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Advanced Numerical Analysis |
Lecture 8 - Gram-Schmidt Process and Generation of Orthogonal Sets |
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Advanced Numerical Analysis |
Lecture 9 - Problem Discretization Using Appropriation Theory |
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Advanced Numerical Analysis |
Lecture 10 - Weierstrass Theorem and Polynomial Approximation |
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Advanced Numerical Analysis |
Lecture 11 - Taylor Series Approximation and Newton's Method |
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Advanced Numerical Analysis |
Lecture 12 - Solving ODE - BVPs Using Firute Difference Method |
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Advanced Numerical Analysis |
Lecture 13 - Solving ODE - BVPs and PDEs Using Finite Difference Method |
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Advanced Numerical Analysis |
Lecture 14 - Finite Difference Method (Continued...) and Polynomial Interpolations |
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Advanced Numerical Analysis |
Lecture 15 - Polynomial and Function Interpolations,Orthogonal Collocations Method for Solving ODE -BVPs |
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Advanced Numerical Analysis |
Lecture 16 - Orthogonal Collocations Method for Solving ODE - BVPs and PDEs |
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Advanced Numerical Analysis |
Lecture 17 - Least Square Approximations, Necessary and Sufficient Conditions for Unconstrained Optimization |
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Advanced Numerical Analysis |
Lecture 18 - Least Square Approximations -Necessary and Sufficient Conditions for Unconstrained Optimization Least Square Approximations ( Continued....) |
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Advanced Numerical Analysis |
Lecture 19 - Linear Least Square Estimation and Geometric Interpretation of the Least Square Solution |
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Advanced Numerical Analysis |
Lecture 20 - Geometric Interpretation of the Least Square Solution (Continued...) and Projection Theorem in a Hilbert Spaces |
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Advanced Numerical Analysis |
Lecture 21 - Projection Theorem in a Hilbert Spaces (Continued...) and Approximation Using Orthogonal Basis |
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Advanced Numerical Analysis |
Lecture 22 - Discretization of ODE-BVP using Least Square Approximation |
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Advanced Numerical Analysis |
Lecture 23 - Discretization of ODE-BVP using Least Square Approximation and Gelarkin Method |
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Advanced Numerical Analysis |
Lecture 24 - Model Parameter Estimation using Gauss-Newton Method |
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Advanced Numerical Analysis |
Lecture 25 - Solving Linear Algebraic Equations and Methods of Sparse Linear Systems |
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Advanced Numerical Analysis |
Lecture 26 - Methods of Sparse Linear Systems (Continued...) and Iterative Methods for Solving Linear Algebraic Equations |
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Advanced Numerical Analysis |
Lecture 27 - Iterative Methods for Solving Linear Algebraic Equations |
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Advanced Numerical Analysis |
Lecture 28 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Eigenvalues |
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Advanced Numerical Analysis |
Lecture 29 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms |
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Advanced Numerical Analysis |
Lecture 30 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms (Continued...) |
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Advanced Numerical Analysis |
Lecture 31 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis (Continued...) |
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Advanced Numerical Analysis |
Lecture 32 - Optimization Based Methods for Solving Linear Algebraic Equations: Gradient Method |
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Advanced Numerical Analysis |
Lecture 33 - Conjugate Gradient Method, Matrix Conditioning and Solutions of Linear Algebraic Equations |
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Advanced Numerical Analysis |
Lecture 34 - Matrix Conditioning and Solutions and Linear Algebraic Equations (Continued...) |
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Advanced Numerical Analysis |
Lecture 35 - Matrix Conditioning (Continued...) and Solving Nonlinear Algebraic Equations |
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Advanced Numerical Analysis |
Lecture 36 - Solving Nonlinear Algebraic Equations: Wegstein Method and Variants of Newton's Method |
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Advanced Numerical Analysis |
Lecture 37 - Solving Nonlinear Algebraic Equations: Optimization Based Methods |
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Advanced Numerical Analysis |
Lecture 38 - Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis of Iterative Solution Techniques |
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Advanced Numerical Analysis |
Lecture 39 - Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis (Continued...) and Solving ODE-IVPs |
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Advanced Numerical Analysis |
Lecture 40 - Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Basic Concepts |
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Advanced Numerical Analysis |
Lecture 41 - Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Runge Kutta Methods |
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Advanced Numerical Analysis |
Lecture 42 - Solving ODE-IVPs : Runge Kutta Methods (Continued...) and Multi-step Methods |
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Advanced Numerical Analysis |
Lecture 43 - Solving ODE-IVPs : Generalized Formulation of Multi-step Methods |
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Advanced Numerical Analysis |
Lecture 44 - Solving ODE-IVPs : Multi-step Methods (Continued...) and Orthogonal Collocations Method |
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Advanced Numerical Analysis |
Lecture 45 - Solving ODE-IVPs: Selection of Integration Interval and Convergence Analysis of Solution Schemes |
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Advanced Numerical Analysis |
Lecture 46 - Solving ODE-IVPs: Convergence Analysis of Solution Schemes (Continued...) |
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Advanced Numerical Analysis |
Lecture 47 - Solving ODE-IVPs: Convergence Analysis of Solution Schemes (Continued...) and Solving ODE-BVP using Single Shooting Method |
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Advanced Numerical Analysis |
Lecture 48 - Methods for Solving System of Differential Algebraic Equations |
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Advanced Numerical Analysis |
Lecture 49 - Methods for Solving System of Differential Algebraic Equations (Continued...) and Concluding Remarks |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 1 - History of the theory of Natural Selection - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 2 - History of the theory of Natural Selection - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 3 - Exponential growth models |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 4 - Logistic Growth Models - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 5 - Logistic Growth Models - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 6 - Modelling selection - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 7 - Modelling Selection - 2 : Two species |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 8 - Modelling Selection - 3 : Two and more species |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 9 - Modelling Mutations - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 10 - Modelling Mutations - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 11 - Modelling Mutations - 3 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 12 - Genetic Code and Sequence Spaces |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 13 - Sequence Spaces as Networks |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 14 - Sequence Space to Fitness Landscape |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 15 - Properties of Fitness Landscapes and Quasi-species |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 16 - Integrating Reproduction, Selection and Mutation |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 17 - Obtaining Fitness Landscapes Experimentally |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 18 - NK Model of Fitness Landscape |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 19 - Modelling Evolution on Fitness Landscapes - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 20 - Modelling Evolution on Fitness Landscapes - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 21 - Modelling Evolution on Fitness Landscapes - 3 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 22 - Role of Randomness in Evolution |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 23 - Genetic Drift in Evolution of Microbial Populations |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 24 - Dynamics of a Moran Process without Selection |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 25 - Dynamics of a Moran Process without Selection |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 26 - Evolution, Selection, and Genetic Drift |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 27 - Representing Microbial Evolution |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 28 - Estimating Timescales of Evolution |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 29 - Estimating the Speed of Microbial Evolution |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 30 - Evolutionary Dynamics when Mutations are Rare |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 31 - Evolutionary Dynamics when Mutations are Rapid - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 32 - Evolutionary Dynamics when Mutations are Rapid - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 33 - Evolutionary Dynamics when Mutations are Rapid - 3 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 34 - Evolutionary Game Theory - 1 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 35 - Evolutionary Game Theory - 2 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 36 - Evolutionary Game Theory - 3 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 37 - Evolutionary Game Theory - 4 |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 38 - Evolutionary Game Theory Applied to Moran Process |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 39 - Evolutionary Games During Weak Selection |
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NOC:Introduction to Evolutionary Dynamics |
Lecture 40 - Evolutionary Dynamics of HIV |
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NOC:Heat Transfer |
Lecture 1 - Introduction |
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NOC:Heat Transfer |
Lecture 2 - Introduction to Conduction |
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NOC:Heat Transfer |
Lecture 3 - Energy Balance |
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NOC:Heat Transfer |
Lecture 4 - 1D Steadystate Conduction - Resistance Concept |
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NOC:Heat Transfer |
Lecture 5 - Resistances in Composite Wall Case |
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NOC:Heat Transfer |
Lecture 6 - Resistances in Radial Systems |
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NOC:Heat Transfer |
Lecture 7 - Heat Generation - I Plane and Cylindrical Wall |
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NOC:Heat Transfer |
Lecture 8 - Heat Generation - II Problem; Introduction to Extended Surfaces |
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NOC:Heat Transfer |
Lecture 9 - Extended Surfaces I - General Formulation |
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NOC:Heat Transfer |
Lecture 10 - Extended Surfaces II - Fixed Cross-section Area |
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NOC:Heat Transfer |
Lecture 11 - Extended Surfaces III - Varying Cross-section Area |
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NOC:Heat Transfer |
Lecture 12 - 2D Plane Wall |
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NOC:Heat Transfer |
Lecture 13 - Transient Analyses I : Lumped Capacitance Method |
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NOC:Heat Transfer |
Lecture 14 - Transient Analyses II : Full Method |
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NOC:Heat Transfer |
Lecture 15 - Transient Analyses : Semi-infinite Case |
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NOC:Heat Transfer |
Lecture 16 - Introduction to Convective Heat Transfer |
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NOC:Heat Transfer |
Lecture 17 - Heat and Mass Transport Coefficients |
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NOC:Heat Transfer |
Lecture 18 - Boundary Layer : Momentum, Thermal and Concentration |
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NOC:Heat Transfer |
Lecture 19 - Laminar and Turbulent Flows; Momentum Balance |
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NOC:Heat Transfer |
Lecture 20 - Energy and Mass Balances; Boundary Layer Approximations |
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NOC:Heat Transfer |
Lecture 21 - Order of Magnitude Analysis |
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NOC:Heat Transfer |
Lecture 22 - Transport Coefficients |
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NOC:Heat Transfer |
Lecture 23 - Relationship between Momentum, Thermal and Concentration Boundary Layer |
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NOC:Heat Transfer |
Lecture 24 - Reynolds and Chilton-Colburn Analogies |
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NOC:Heat Transfer |
Lecture 25 - Forced Convection : Introduction |
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NOC:Heat Transfer |
Lecture 26 - Flow Past Flat Plate I - Method of Blasius |
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NOC:Heat Transfer |
Lecture 27 - Flow Past Flat Plate II - Correlations for Heat and Mass Transport |
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NOC:Heat Transfer |
Lecture 28 - Flow Past Cylinders |
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NOC:Heat Transfer |
Lecture 29 - Flow through Pipes - I |
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NOC:Heat Transfer |
Lecture 30 - Flow through Pipes - II |
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NOC:Heat Transfer |
Lecture 31 - Flow through Pipes - III |
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NOC:Heat Transfer |
Lecture 32 - Flow through Pipes - IV - Mixing-cup Temperature |
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NOC:Heat Transfer |
Lecture 33 - Flow through Pipes - V - Log mean Temperature Difference |
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NOC:Heat Transfer |
Lecture 34 - Flow through Pipes - VI - Correlations for Laminar and Turbulent Conditions |
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NOC:Heat Transfer |
Lecture 35 - Example problems : Forced Convection |
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NOC:Heat Transfer |
Lecture 36 - Introduction to Free/Natural Convection |
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NOC:Heat Transfer |
Lecture 37 - Heated Plate in a Quiescent Fluid - I |
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NOC:Heat Transfer |
Lecture 38 - Heated Plate in a Quiescent Fluid - II |
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NOC:Heat Transfer |
Lecture 39 - Boiling - I |
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NOC:Heat Transfer |
Lecture 40 - Boiling - II |
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NOC:Heat Transfer |
Lecture 41 - Condensation - I |
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NOC:Heat Transfer |
Lecture 42 - Condensation - II |
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NOC:Heat Transfer |
Lecture 43 - Radiation : Introduction |
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NOC:Heat Transfer |
Lecture 44 - Spectral Intensity |
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NOC:Heat Transfer |
Lecture 45 - Radiation : Spectral properties, Blackbody |
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NOC:Heat Transfer |
Lecture 46 - Properties of a Blackbody |
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NOC:Heat Transfer |
Lecture 47 - Surface Adsorption |
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NOC:Heat Transfer |
Lecture 48 - Kirchoff’s Law |
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NOC:Heat Transfer |
Lecture 49 - Radiation Exchange - View Factor |
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NOC:Heat Transfer |
Lecture 50 - View Factor Examples |
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NOC:Heat Transfer |
Lecture 51 - View Factor - Inside Sphere Method, Blackbody Radiation Exchange |
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NOC:Heat Transfer |
Lecture 52 - Diffuse, Gray Surfaces in an Enclosure |
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NOC:Heat Transfer |
Lecture 53 - Resistances - Oppenheim Matrix Method |
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NOC:Heat Transfer |
Lecture 54 - Resistances - Examples |
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NOC:Heat Transfer |
Lecture 55 - More Examples: Volumetric Radiation |
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NOC:Heat Transfer |
Lecture 56 - Introduction and Examples |
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NOC:Heat Transfer |
Lecture 57 - Parallel Flow Heat Exchangers |
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NOC:Heat Transfer |
Lecture 58 - LMTD I |
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NOC:Heat Transfer |
Lecture 59 - Shell and Tube Heat Exchangers |
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NOC:Heat Transfer |
Lecture 60 - Epsilon-NTU Method |
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NOC:Chemical Reaction Engineering-II |
Lecture 1 - Introduction |
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NOC:Chemical Reaction Engineering-II |
Lecture 2 - Introduction to catalysis and catalytic processes |
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NOC:Chemical Reaction Engineering-II |
Lecture 3 - Catalyst properties and classification |
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NOC:Chemical Reaction Engineering-II |
Lecture 4 - Steps in catalysis |
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NOC:Chemical Reaction Engineering-II |
Lecture 5 - Adsorption isotherm |
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NOC:Chemical Reaction Engineering-II |
Lecture 6 - Surface reaction |
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NOC:Chemical Reaction Engineering-II |
Lecture 7 - Rate controlling steps and Rate law |
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NOC:Chemical Reaction Engineering-II |
Lecture 8 - Rate law: Pseudo-steady state hypothesis |
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NOC:Chemical Reaction Engineering-II |
Lecture 9 - Heterogeneous data analysis for reactor design - I |
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NOC:Chemical Reaction Engineering-II |
Lecture 10 - Heterogeneous data analysis for reactor design - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 11 - Design of reactors: PBR and CSTR |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 12 - Case study: Chemical Vapor Deposition |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 13 - Catalyst deactivation - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 14 - Catalyst deactivation - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 15 - Catalyst deactivation - III |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 16 - Catalyst deactivation - IV : Reactor design |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 17 - Diffusional effects: Introduction |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 18 - Internal diffusion effects: Model development |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 19 - Non-dimensionalization: Thiele modulus |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 20 - Concentration profile |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 21 - Internal effectiveness factor - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 22 - Internal effectiveness factor - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 23 - Internal effectiveness factor - III: Exothermic and endothermic reactions |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 24 - Falsification of kinetics |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 25 - External mass transport limitations: Mass transfer coefficient |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 26 - Estimation of mass transfer coefficient |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 27 - Mass transfer to a single particle with reaction |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 28 - Packed-bed reactor design: External mass transfer limitations |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 29 - Mass transfer coefficient in Packed-beds |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 30 - Estimation of conversion in Packed-bed reactor: Example problem |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 31 - Overall effectiveness factor - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 32 - Overall effectiveness factor - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 33 - Identification of internal diffusion and reaction-limited regimes |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 34 - Packed-bed reactor design |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 35 - Generalized criterion for diffusion and reaction-limited conditions |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 36 - Network of first order reactions |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 37 - Use of experimental data |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 38 - Packed-bed reactor design: External and Internal resistances |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 39 - Fluidized bed reactor design - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 40 - Fluidized bed reactor design - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 41 - Fluidized bed reactor design - III |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 42 - Fluidized bed reactor design - IV |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 43 - Fluid-solid noncatalytic reactions - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 44 - Fluid-solid noncatalytic reactions - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 45 - Fluid-solid noncatalytic reactions - III |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 46 - Fluid-solid noncatalytic reactions - IV |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 47 - Fluid-solid noncatalytic reactions - V |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 48 - Fluid-solid noncatalytic reactions - VI |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 49 - Residence time distribution (RTD): Introduction |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 50 - RTD: Non-ideal reactors |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 51 - Measurement of RTD - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 52 - Measurement of RTD - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 53 - RTD function |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 54 - Properties of RTD function |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 55 - Reactor diagnostics and troubleshooting - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 56 - Reactor diagnostics and troubleshooting - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 57 - Modeling nonideal reactors - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 58 - Modeling nonideal reactors - II |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 59 - Non-ideal reactors: Zero parameter models - I |
Link |
NOC:Chemical Reaction Engineering-II |
Lecture 60 - Non-ideal reactors: Zero parameter models - II |
Link |
NOC:Chemical Process Control |
Lecture 1 - Motivation for process control |
Link |
NOC:Chemical Process Control |
Lecture 2 - Functions of process control system |
Link |
NOC:Chemical Process Control |
Lecture 3 - Common control strategies |
Link |
NOC:Chemical Process Control |
Lecture 4 - Components of process control system |
Link |
NOC:Chemical Process Control |
Lecture 5 - Introduction to process dynamics |
Link |
NOC:Chemical Process Control |
Lecture 6 - First principle dynamic models |
Link |
NOC:Chemical Process Control |
Lecture 7 - Empirical and gray box models |
Link |
NOC:Chemical Process Control |
Lecture 8 - Degree of freedom analysis |
Link |
NOC:Chemical Process Control |
Lecture 9 - Introduction to first order dynamical systems |
Link |
NOC:Chemical Process Control |
Lecture 10 - Linearization of process dynamics |
Link |
NOC:Chemical Process Control |
Lecture 11 - Response to step input |
Link |
NOC:Chemical Process Control |
Lecture 12 - Response to sinusoidal input |
Link |
NOC:Chemical Process Control |
Lecture 13 - Introduction to second order dynamical systems |
Link |
NOC:Chemical Process Control |
Lecture 14 - Examples of second order dynamical systems |
Link |
NOC:Chemical Process Control |
Lecture 15 - Response to step input |
Link |
NOC:Chemical Process Control |
Lecture 16 - Effect of damping coefficient |
Link |
NOC:Chemical Process Control |
Lecture 17 - Higher order dynamics |
Link |
NOC:Chemical Process Control |
Lecture 18 - Approximation as FOPDT model |
Link |
NOC:Chemical Process Control |
Lecture 19 - Numerator dynamics |
Link |
NOC:Chemical Process Control |
Lecture 20 - Prediction of step response |
Link |
NOC:Chemical Process Control |
Lecture 21 - Block diagram representation |
Link |
NOC:Chemical Process Control |
Lecture 22 - ON-OFF control |
Link |
NOC:Chemical Process Control |
Lecture 23 - Proportional control |
Link |
NOC:Chemical Process Control |
Lecture 24 - Proportional-Integral control |
Link |
NOC:Chemical Process Control |
Lecture 25 - PID control |
Link |
NOC:Chemical Process Control |
Lecture 26 - Limitations of PID controllers |
Link |
NOC:Chemical Process Control |
Lecture 27 - Stability of dynamical processes |
Link |
NOC:Chemical Process Control |
Lecture 28 - Laplace domain analysis - Part I |
Link |
NOC:Chemical Process Control |
Lecture 29 - Laplace domain analysis - Part II |
Link |
NOC:Chemical Process Control |
Lecture 30 - Frequency response |
Link |
NOC:Chemical Process Control |
Lecture 31 - Frequency domain analysis |
Link |
NOC:Chemical Process Control |
Lecture 32 - Synthesis problem |
Link |
NOC:Chemical Process Control |
Lecture 33 - Selection problem |
Link |
NOC:Chemical Process Control |
Lecture 34 - Criteria-based controller tuning |
Link |
NOC:Chemical Process Control |
Lecture 35 - Heuristics-based controller tuning |
Link |
NOC:Chemical Process Control |
Lecture 36 - Direct synthesis-based controller tuning |
Link |
NOC:Chemical Process Control |
Lecture 37 - Frequency response-based controller tuning |
Link |
NOC:Chemical Process Control |
Lecture 38 - Cascade control |
Link |
NOC:Chemical Process Control |
Lecture 39 - Split range control and override control |
Link |
NOC:Chemical Process Control |
Lecture 40 - Auctioneering, ratio and inreferential control |
Link |
NOC:Chemical Process Control |
Lecture 41 - Openloop control and Internal model control |
Link |
NOC:Chemical Process Control |
Lecture 42 - Dynamic Matrix and Model predictive control |
Link |
NOC:Chemical Process Control |
Lecture 43 - Introduction to multivariable control |
Link |
NOC:Chemical Process Control |
Lecture 44 - Input-output pairing |
Link |
NOC:Chemical Process Control |
Lecture 45 - Tuning of multi-loop SISO controller |
Link |
NOC:Chemical Process Control |
Lecture 46 - Introduction to batch process control |
Link |
NOC:Chemical Process Control |
Lecture 47 - Programmable logic control |
Link |
NOC:Chemical Process Control |
Lecture 48 - Batch to batch control |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 1 - Introduction |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 2 - Coupled, linear, spring-mass systems |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 3 - Coupled, linear, spring-mass systems (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 4 - Coupled, linear, spring-mass systems (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 5 - Coupled, linear, spring-mass system: continuum limit |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 6 - Normal modes of a string fixed at both ends |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 7 - Vibrations of clamped membranes |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 8 - Vibrations of clamped membranes (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 9 - Introduction to Jacobian elliptic functions |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 10 - The non-linear pendulum |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 11 - The non-linear pendulum (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 12 - Time period of the non-linear pendulum |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 13 - Introduction to perturbation methods |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 14 - Perturbation methods (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 15 - Non-dimensionalisation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 16 - Perturbative solution to the projectile equation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 17 - Perturbative solution to the nonlinear pendulum |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 18 - Lindstedt-Poincare technique |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 19 - Method of multiple scales |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 20 - Method of multiple scales (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 21 - Multiple scale analysis for damped-harmonic oscillator |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 22 - Duffing equation using multiple scales |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 23 - Duffing equation (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 24 - Kapitza pendulum |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 25 - Introduction to Floquet theory |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 26 - Floquet theorem (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 27 - Floquet analysis of the Mathieu equation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 28 - Introduction to waves on an interface |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 29 - Linearized wave equations in deep water |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 30 - Linearized wave equations in deep water: dispersion relation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 31 - Linearised deep-water surface gravity waves (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 32 - Standing and travelling waves in deep water |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 33 - Cauchy-Poisson initial value problem for surface-gravity waves in deep water |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 34 - Cauchy-Poisson problem (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 35 - Cauchy-Poisson problem in cylindrical geometry |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 36 - Cauchy-Poisson problem in cylindrical geometry (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 37 - Group-velocity and the Cauchy-Poisson problem |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 38 - Cauchy-Poisson problem for delta function initial condition |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 39 - Cauchy-Poisson problem for delta function initial condition (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 40 - Capillary-gravity waves |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 41 - Waves on a pool of finite depth |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 42 - Axisymmetric Cauchy-Poisson problem visualisation: the pebble in the deep pond problem |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 43 - Rayleigh-Plateau capillary instability |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 44 - Rayleigh-Plateau capillary instability (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 45 - Rayleigh-Plateau capillary instability on thin film coating a rod |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 46 - Rayleigh-Plateau capillary instability of a cylindrical air column in a liquid |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 47 - Mechanism of the Rayleigh-Plateau instability |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 48 - Shape oscillations of a spherical interface |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 49 - Shape oscillations of a spherical interface (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 50 - Shape oscillations of a spherical interface (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 51 - Analysis of l=0 and l=1 modes for a spherical drop |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 52 - Faraday waves on an interface - stability of time dependent base states |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 53 - Mathieu equation for Faraday waves |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 54 - Applications of Faraday waves - atomisation and spray formation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 55 - Waves and instability on density stratified shear flows - the KH model |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 56 - Limits of KH dispersion relation: Rayleigh-Taylor instability |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 57 - KH dispersion relation : model of wind wave generation |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 58 - Helmholtz instability of a vortex sheet and summary |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 59 - Derivation of the Stokes travelling wave |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 60 - Derivation of the Stokes travelling wave (Continued...) |
Link |
NOC:Introduction to Interfacial Waves |
Lecture 61 - Derivation of the Stokes travelling wave (Continued...) |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 1 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 2 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 3 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 4 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 5 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 6 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 7 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 8 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 9 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 10 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 11 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 12 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 13 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 14 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 15 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 16 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 17 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 18 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 19 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 20 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 21 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 22 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 23 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 24 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 25 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 26 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 27 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 28 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 29 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 30 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 31 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 32 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 33 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 34 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 35 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 36 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 37 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 38 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 39 |
Link |
Heterogeneous Catalysis and Catalytic Processes |
Lecture 40 |
Link |
Interfacial Engineering |
Lecture 1 - General Introduction Definitions |
Link |
Interfacial Engineering |
Lecture 2 - General Introduction, Definitions, Surface Tension |
Link |
Interfacial Engineering |
Lecture 3 - Surface Tension Free Energies and Adsorption |
Link |
Interfacial Engineering |
Lecture 4 - Properties over Curved Surfaces |
Link |
Interfacial Engineering |
Lecture 5 - Total Surface Energy |
Link |
Interfacial Engineering |
Lecture 6 - Interfacial Tension Entropy, Cohesion, Adhesion |
Link |
Interfacial Engineering |
Lecture 7 - Cohesion, Adhesion and Spreading |
Link |
Interfacial Engineering |
Lecture 8 - Spreading from Liquids and Solids |
Link |
Interfacial Engineering |
Lecture 9 - Spreading, Interfacial Tensions, Surface Tensions |
Link |
Interfacial Engineering |
Lecture 10 - Spreading, Contact Angles Free Energies |
Link |
Interfacial Engineering |
Lecture 11 - Spreading/Contact Angles Rough Surfaces, Free Energies |
Link |
Interfacial Engineering |
Lecture 12 - Spreading/Contact Angles Work of Adhesion, De-wetting |
Link |
Interfacial Engineering |
Lecture 13 - Work of Adhesion, Surface and Interfacial Tensions |
Link |
Interfacial Engineering |
Lecture 14 - Surface and Interfacial Tensions: Drop Weight and Wilhelmy Plate Methods |
Link |
Interfacial Engineering |
Lecture 15 - Surface and Interfacial Tensions: Wilhelmy Plate, Pendant Drop and Maximum Bubble Pressure Methods |
Link |
Interfacial Engineering |
Lecture 16 - Wetting Balance Method Spreading Coefficient Work of Adhesion Sessile Drop Method, Positive S |
Link |
Interfacial Engineering |
Lecture 17 - Indirect and Direct Methods for Positive S, Adhesion Energies Interfacial Potentials |
Link |
Interfacial Engineering |
Lecture 18 - Surface and Interfacial Potentials Distribution and Contact Potentials |
Link |
Interfacial Engineering |
Lecture 19 - Diffusion Potential Surface and Interfacial Potentials Components of Contact Potential |
Link |
Interfacial Engineering |
Lecture 20 - Electrically Charged Monolayers Gouy Theory |
Link |
Interfacial Engineering |
Lecture 21 - Equations of State, Cohesion Repulsion, Limiting Area |
Link |
Interfacial Engineering |
Lecture 22 - Condensed and Liquid Expanded Monolayers Phase Transformations |
Link |
Interfacial Engineering |
Lecture 23 - Films of Polymers Molecular Weight, Surface Viscosity Drag, Canal Method |
Link |
Interfacial Engineering |
Lecture 24 - Canal Method Joly's Semi-Empirical Correction Rotational Torsional Surface Viscometer Compressional Moduli |
Link |
Interfacial Engineering |
Lecture 25 - Magnitudes of Surface Compressional Moduli Surface Waves and Ripples |
Link |
Interfacial Engineering |
Lecture 26 - Surface waves and Ripples, Velocity Effect of Surface Tension and Surface Compressional Modulus Rates of adsorption and absorption Damping |
Link |
Interfacial Engineering |
Lecture 27 - Surface waves and ripples,velocity effect of surface tension and surface compressional modulus damping for clean and contaminated,surfaces,fiber from monolayers |
Link |
Interfacial Engineering |
Lecture 28 - Shear Elastic Moduli,Yield Stress Fibres from MLs, Surface Reactions |
Link |
Interfacial Engineering |
Lecture 29 - Surface Reactions, Comparison with Bulk-Phase Reactions Steric Factors, Inhibition |
Link |
Interfacial Engineering |
Lecture 30 - Hydrolyses of Esters by Alkali Acid or Enzyme Photochemical Reactions in Monolayers Polymerization in MLs, Lactonization |
Link |
Interfacial Engineering |
Lecture 31 - Catalytic Effects Reactions in Emulsions Complex Formation |
Link |
Interfacial Engineering |
Lecture 32 - Complex Formation Penetration into Monolayers Thermodynamics of Penetration Adsorption from Vapour Phase Mass Transfer |
Link |
Interfacial Engineering |
Lecture 33 - Introductory Concepts Resistances and their Magnitudes Evaporation and its Retardation |
Link |
Interfacial Engineering |
Lecture 34 - Evaporation and its Retardation Resistances and their Analysis Diffusional Resistance in Gas Phase |
Link |
Interfacial Engineering |
Lecture 35 - Resistances in Liquid Phase and Interface and Their Importance Some Effects and Applications, Theory |
Link |
Interfacial Engineering |
Lecture 36 - Surface Instability Theories of Mass Transfer Experiments on static and Dynamic Systems |
Link |
Interfacial Engineering |
Lecture 37 - Colloida, Aerosols, Emulsions Foams, Coagulation Smoluchowski's Theory |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 1 (1) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 2 (1A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 3 (2) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 4 (2A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 5 (3) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 6 (3A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 7 (4) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 8 (4A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 9 (5) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 10 (5A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 11 (6) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 12 (6A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 13 (7) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 14 (7A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 15 (8) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 16 (8A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 17 (8B) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 18 (9) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 19 (9A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 20 (10) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 21 (10A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 22 (10B) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 23 (11) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 24 (12) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 25 (12A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 26 (12B) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 27 (13) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 28 (13A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 29 (14) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 30 (14A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 31 (15) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 32 (15A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 33 (16) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 34 (16A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 35 (17) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 36 (17A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 37 (18) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 38 (18A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 39 (19) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 40 (19A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 41 (20) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 42 (20A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 43 (20B) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 44 (21) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 45 (21A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 46 (22) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 47 (22A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 48 (23) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 49 (23A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 50 (24) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 51 (24A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 52 (25) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 53 (25A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 54 (26) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 55 (26A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 56 (25) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 57 (27) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 58 (28) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 59 (28A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 60 (29) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 61 (29A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 62 (30) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 63 (30A) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 64 (31) |
Link |
NOC:Fluid Mechanics and its Applications |
Lecture 65 (31A) |
Link |
Heat Transfer |
Lecture 1 - Introduction to heat transfer |
Link |
Heat Transfer |
Lecture 2 - General heat conduction equation |
Link |
Heat Transfer |
Lecture 3 - One dimensional steady state conduction in rectangular coordinate |
Link |
Heat Transfer |
Lecture 4 - One dimensional steady state conduction in cylindrical and spherical coordinate |
Link |
Heat Transfer |
Lecture 5 - Critical and optimum insulation |
Link |
Heat Transfer |
Lecture 6 - Extended surface heat transfer - 1 |
Link |
Heat Transfer |
Lecture 7 - Extended surface heat transfer - 2 |
Link |
Heat Transfer |
Lecture 8 - Analysis of lumped parameter model |
Link |
Heat Transfer |
Lecture 9 - Transient heat flow in semi infinite solid |
Link |
Heat Transfer |
Lecture 10 - Infinite body subjected to sudden convective |
Link |
Heat Transfer |
Lecture 11 - Graphical solutions of unsteady state heat conduction problem |
Link |
Heat Transfer |
Lecture 12 - Dimensional analysis for forced convection |
Link |
Heat Transfer |
Lecture 13 - Dimensional analysis for free convection |
Link |
Heat Transfer |
Lecture 14 - Heat transfer co-relations for laminar and internal flows |
Link |
Heat Transfer |
Lecture 15 - Heat transfer co-relations for turbulent and internal flows |
Link |
Heat Transfer |
Lecture 16 - Co-relation for turbulent and external flows |
Link |
Heat Transfer |
Lecture 17 - Heat transfer co-relations for flow across tube banks |
Link |
Heat Transfer |
Lecture 18 - Momentum and heat transfer analogies |
Link |
Heat Transfer |
Lecture 19 - Boundary layer heat transfer |
Link |
Heat Transfer |
Lecture 20 - Boundary layer equations |
Link |
Heat Transfer |
Lecture 21 - Approximate analysis in boundary layer |
Link |
Heat Transfer |
Lecture 22 - Theoretical concepts of natural / free convention heat transfer |
Link |
Heat Transfer |
Lecture 23 - Emperical relations for free convention heat transfer |
Link |
Heat Transfer |
Lecture 24 - Condensation heat transfer over vertical plate |
Link |
Heat Transfer |
Lecture 25 - Condensation heat transfer for various conditions and geometries |
Link |
Heat Transfer |
Lecture 26 - Fundamentals of boiling heat transfer |
Link |
Heat Transfer |
Lecture 27 - Boiling heat transfer co-relations |
Link |
Heat Transfer |
Lecture 28 - Classification of heat exchangers |
Link |
Heat Transfer |
Lecture 29 - Various types of shell and tube heat exchangers |
Link |
Heat Transfer |
Lecture 30 - Various types of compact heat exchangers |
Link |
Heat Transfer |
Lecture 31 - Effectiveness-NTU, method of heat exchanger analysis |
Link |
Heat Transfer |
Lecture 32 - Design of double pipe heat exchanger |
Link |
Heat Transfer |
Lecture 33 - Design of shell and tube heat exchanger |
Link |
Heat Transfer |
Lecture 34 - Introduction to evaporation and evaporators |
Link |
Heat Transfer |
Lecture 35 - Evaporation principles and evaporator performance |
Link |
Heat Transfer |
Lecture 36 - Evaporator calculations |
Link |
Heat Transfer |
Lecture 37 - Introduction to radiation heat transfer |
Link |
Heat Transfer |
Lecture 38 - Radiation intensity and radiation view factor |
Link |
Heat Transfer |
Lecture 39 - Radiation heat exchange |
Link |
Heat Transfer |
Lecture 40 - Radiation shield and gas radiation |
Link |
Mass Transfer Operations I |
Lecture 1 - Introduction to Mass Transfer |
Link |
Mass Transfer Operations I |
Lecture 2 - Molecular Diffusion |
Link |
Mass Transfer Operations I |
Lecture 3 - Fick’s Law of Diffusion |
Link |
Mass Transfer Operations I |
Lecture 4 - Steady state molecular diffusion in fluids - Part I |
Link |
Mass Transfer Operations I |
Lecture 5 - Steady state molecular diffusion in fluids - Part II |
Link |
Mass Transfer Operations I |
Lecture 6 - Diffusion coefficient: Measurement and Prediction - Part I |
Link |
Mass Transfer Operations I |
Lecture 7 - Diffusion Coefficient: Measurement and Prediction - Part II |
Link |
Mass Transfer Operations I |
Lecture 8 - Multicomponent Diffusion and Diffusivity in Solids |
Link |
Mass Transfer Operations I |
Lecture 9 - Concept of Mass Transfer Coefficient |
Link |
Mass Transfer Operations I |
Lecture 10 - Dimensionless Groups and Co-relations for Convective |
Link |
Mass Transfer Operations I |
Lecture 11 - Mass Transfer co-efficient in Laminar Flow Condition |
Link |
Mass Transfer Operations I |
Lecture 12 - Boundary Layer Theory and Film Theory in Mass Transfer |
Link |
Mass Transfer Operations I |
Lecture 13 - Mass Transfer Coefficients in Terbulant Flow |
Link |
Mass Transfer Operations I |
Lecture 14 - Interphase Mass Transfer and Mass Transfer Theories - Part I |
Link |
Mass Transfer Operations I |
Lecture 15 - Interphase Mass Transfer and Mass Transfer Theories - Part II |
Link |
Mass Transfer Operations I |
Lecture 16 - Interphase Mass Transfer and Mass Transfer Theories - Part III |
Link |
Mass Transfer Operations I |
Lecture 17 - Agitated and Sparged Vassels |
Link |
Mass Transfer Operations I |
Lecture 18 - Tray Column - Part I |
Link |
Mass Transfer Operations I |
Lecture 19 - Tray Column - Part II |
Link |
Mass Transfer Operations I |
Lecture 20 - Packed Tower |
Link |
Mass Transfer Operations I |
Lecture 21 - Introduction to Absorption and Solvent selection |
Link |
Mass Transfer Operations I |
Lecture 22 - Packed Tower Design - Part I |
Link |
Mass Transfer Operations I |
Lecture 23 - Packed Tower Design - Part II |
Link |
Mass Transfer Operations I |
Lecture 24 - Packed Tower Design - Part III |
Link |
Mass Transfer Operations I |
Lecture 25 - Mass Transfer Coefficients Correlation and HETP Concept |
Link |
Mass Transfer Operations I |
Lecture 26 - Tray Tower Design and Introduction to Multicomponent System |
Link |
Mass Transfer Operations I |
Lecture 27 - Introduction to Distillation and Phas diagrams |
Link |
Mass Transfer Operations I |
Lecture 28 - Azeotropes and Enthalpy Concentration Diagrams |
Link |
Mass Transfer Operations I |
Lecture 29 - Flash Distillation |
Link |
Mass Transfer Operations I |
Lecture 30 - Batch and Steam Distillation |
Link |
Mass Transfer Operations I |
Lecture 31 - Fractional Distillation |
Link |
Mass Transfer Operations I |
Lecture 32 - Fractional Distillation: McCabe Thiele Method |
Link |
Mass Transfer Operations I |
Lecture 33 - Fractional Distillation: Minimum Reflux and Pinch Point |
Link |
Mass Transfer Operations I |
Lecture 34 - Fractional Distillation: Subcooled Reflux ,Tray Efficiency and Use of Open Steam |
Link |
Mass Transfer Operations I |
Lecture 35 - Fractional Distillation: Multiple Feeds and Side Stream |
Link |
Mass Transfer Operations I |
Lecture 36 - Multistage Batch Distillation with Reflux |
Link |
Mass Transfer Operations I |
Lecture 37 - Fractional Distillation: Ponchan and Savarit Method |
Link |
Mass Transfer Operations I |
Lecture 38 - Ponchan and Savarit Method and Packed Tower Distillation |
Link |
Mass Transfer Operations I |
Lecture 39 - Multicomponent Distillation |
Link |
Process Design Decisions and Project Economics |
Lecture 1 - General Introduction to the Course and Syllabus |
Link |
Process Design Decisions and Project Economics |
Lecture 2 - Hierarchical Approach to Process Design - I |
Link |
Process Design Decisions and Project Economics |
Lecture 3 - Hierarchical Approach to Process Design - Examples |
Link |
Process Design Decisions and Project Economics |
Lecture 4 - Input Information and Design Aspects of Batch vs. Continuous Process |
Link |
Process Design Decisions and Project Economics |
Lecture 5 - Input / Output Structure of Flowsheet - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 6 - Input / Output Structure of Flowsheet - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 7 - Input / Output Structure of Flowsheet - Part III and Recycle Structure of Flowsheet - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 8 - Recycle Structure of Flowsheet - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 9 - Recycle Structure of Flowsheet - Part III |
Link |
Process Design Decisions and Project Economics |
Lecture 10 - Recycle Structure of Flowsheet - Part IV and Tutorial - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 11 - Tutorial - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 12 - Tutorial - Part III |
Link |
Process Design Decisions and Project Economics |
Lecture 13 - Algorithm and Basic Principles of Reactor Design |
Link |
Process Design Decisions and Project Economics |
Lecture 14 - Reactor Non-ideality, Residence Time Distribution (RTD) and Types of Chemical Reactions & Catalysts |
Link |
Process Design Decisions and Project Economics |
Lecture 15 - Types of Reactors and Selection Criteria |
Link |
Process Design Decisions and Project Economics |
Lecture 16 - Tutorial on Reactor Design and Cost Estimation |
Link |
Process Design Decisions and Project Economics |
Lecture 17 - General Introduction (Types of Separation Processes and Criteria for Selection of the Processes) |
Link |
Process Design Decisions and Project Economics |
Lecture 18 - Guidelines for Design of Separation Systems |
Link |
Process Design Decisions and Project Economics |
Lecture 19 - Design of Distillation Columns - Part I (Sequencing of Columns, Energy Integration / Thermal Coupling of the Columns) |
Link |
Process Design Decisions and Project Economics |
Lecture 20 - Design of Distillation Columns - Part II (Plate and Packed Towers, Number of Plates, Diameter and Height of the Column) |
Link |
Process Design Decisions and Project Economics |
Lecture 21 - Tutorial - Part I (Design of Absorption Column) |
Link |
Process Design Decisions and Project Economics |
Lecture 22 - Tutorial - Part II (Design of Distillation Column) |
Link |
Process Design Decisions and Project Economics |
Lecture 23 - Concepts and Basic Principles of Energy (or Heat) Integration - Part 1 (Composite Curves and ?Tmin) |
Link |
Process Design Decisions and Project Economics |
Lecture 24 - Concepts and Basic Principles of Heat Integration - Part 2 (Problem Table Algorithm and Identification of Energy Targets) |
Link |
Process Design Decisions and Project Economics |
Lecture 25 - Identification of Area and Cost Targets |
Link |
Process Design Decisions and Project Economics |
Lecture 26 - Pinch Technology for Heat Exchanger Network Design |
Link |
Process Design Decisions and Project Economics |
Lecture 27 - Tutorial - I (Composite Curves, Problem Table Algorithm and Enthalpy Intervals) |
Link |
Process Design Decisions and Project Economics |
Lecture 28 - Tutorial - II (Heat Exchanger Network Synthesis Using Pinch Technology) |
Link |
Process Design Decisions and Project Economics |
Lecture 29 - Selection of Process, Design of Flowsheet and Materials Balance |
Link |
Process Design Decisions and Project Economics |
Lecture 30 - Energy Balance, Process Alternatives and Design of the Absorber |
Link |
Process Design Decisions and Project Economics |
Lecture 31 - Rules of Thumb & Their Limitations and Tutorial |
Link |
Process Design Decisions and Project Economics |
Lecture 32 - General Concepts & Principles and Cost Allocation Procedure |
Link |
Process Design Decisions and Project Economics |
Lecture 33 - Lumped Cost Diagram and Cost Allocation Diagram (Case Study of Hydro-dealkylation Process) |
Link |
Process Design Decisions and Project Economics |
Lecture 34 - Assessment of Process Alternatives with Cost Allocation Diagram (Case Study of Hydrodealkylation Process) |
Link |
Process Design Decisions and Project Economics |
Lecture 35 - Tutorial on Lumped Cost Diagram and Cost Allocation Diagram |
Link |
Process Design Decisions and Project Economics |
Lecture 36 - Introduction to Chemical Projects and Their Economic Aspects |
Link |
Process Design Decisions and Project Economics |
Lecture 37 - Selection of the Process and Project Site - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 38 - Selection of the Process and Project Site - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 39 - Project Cost Estimation - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 40 - Project Cost Estimation - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 41 - Simplified Cost Model and Depreciation |
Link |
Process Design Decisions and Project Economics |
Lecture 42 - Time Value of Money |
Link |
Process Design Decisions and Project Economics |
Lecture 43 - Measures of Profitability and Project Evaluation - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 44 - Measures of Profitability and Project Evaluation - Part II |
Link |
Process Design Decisions and Project Economics |
Lecture 45 - Tutorial on Project Economics - Part I |
Link |
Process Design Decisions and Project Economics |
Lecture 46 - Tutorial on Project Economics - Part II |
Link |
NOC:Fluidization Engineering |
Lecture 1 - Introduction |
Link |
NOC:Fluidization Engineering |
Lecture 2 - Particle properties |
Link |
NOC:Fluidization Engineering |
Lecture 3 - Particle / Powder Classifications |
Link |
NOC:Fluidization Engineering |
Lecture 4 - Minimum Fluidization Velocity: Fluid-solid System |
Link |
NOC:Fluidization Engineering |
Lecture 5 - Minimum Fluidization Velocity: Liquid-solid and gas-liquid-solid System |
Link |
NOC:Fluidization Engineering |
Lecture 6 - Flow regime and its map: Gas-solid Fluidization |
Link |
NOC:Fluidization Engineering |
Lecture 7 - Flow regime and its map: Liquid-solid and Gas-liquid-solid Fluidization |
Link |
NOC:Fluidization Engineering |
Lecture 8 - Frictional pressure drop in fluidized bed-fluid-solid system |
Link |
NOC:Fluidization Engineering |
Lecture 9 - Frictional pressure drop in fluidized Bed-Gas-liquid-solid system |
Link |
NOC:Fluidization Engineering |
Lecture 10 - Analysis of Frictional Pressure Drop in Fluidized Bed By Different Models |
Link |
NOC:Fluidization Engineering |
Lecture 11 - Gas Distribution Through Distributor |
Link |
NOC:Fluidization Engineering |
Lecture 12 - Calculation of gas pumping power consumption in fluidized bed |
Link |
NOC:Fluidization Engineering |
Lecture 13 - Bubbling Fluidization Part 1: Bubble Characteristics |
Link |
NOC:Fluidization Engineering |
Lecture 14 - Bubbling Fluidization Part 2: Bubble Characteristics (Continued...) |
Link |
NOC:Fluidization Engineering |
Lecture 15 - Bubbling Fluidization Part 3: Bubble coalescence in three-phase fluidization |
Link |
NOC:Fluidization Engineering |
Lecture 16 - Bubbling Fluidization Part 4: Bubble breakup in three-phase fluidization |
Link |
NOC:Fluidization Engineering |
Lecture 17 - Bubbling Fluidization Part 5: Gas and solid movements at bubble |
Link |
NOC:Fluidization Engineering |
Lecture 18 - Bubbling Fluidization Part 6: Slugging Bed |
Link |
NOC:Fluidization Engineering |
Lecture 19 - Entrainment Characteristics (Part 1) : Entrainment Characteristics |
Link |
NOC:Fluidization Engineering |
Lecture 20 - Entrainment Characteristics (Part 2) : Fast fluidization condition |
Link |
NOC:Fluidization Engineering |
Lecture 21 - Entrainment Characteristics (Part 2) : Elutriation Characteristics |
Link |
NOC:Fluidization Engineering |
Lecture 22 - Entrainment Characteristics (Part 2) : Attrition in Fluidized Bed (Part 1) |
Link |
NOC:Fluidization Engineering |
Lecture 23 - Attrition in Fluidized Bed (Part 2) |
Link |
NOC:Fluidization Engineering |
Lecture 24 - Solid movement, mixing: Gas-fluidized Bed |
Link |
NOC:Fluidization Engineering |
Lecture 25 - Solid segregation: Gas-fluidized bed |
Link |
NOC:Fluidization Engineering |
Lecture 26 - Solid mixing and segregation: Liquid-solid fluidized bed |
Link |
NOC:Fluidization Engineering |
Lecture 27 - Gas Dispersion and Interchange |
Link |
NOC:Fluidization Engineering |
Lecture 28 - Mass transfer in fluidized Bed-Gas-solid system |
Link |
NOC:Fluidization Engineering |
Lecture 29 - Mass transfer in fluidized Bed-Gas-liquid-solid system (Continued...) |
Link |
NOC:Fluidization Engineering |
Lecture 30 - Heat transfer Characteristics |
Link |
NOC:Fluidization Engineering |
Lecture 31 - Fluidized bed reactor design and its performance |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 1 - An Introduction |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 2 - Fluid Mechanics: A Review |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 3 - Solid Mechanics: A Review |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 4 - Rheology of blood |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 5 - Blood morphology |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 6 - Blood flow in a channel |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 7 - Viscometers and Rheometers |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 8 - Viscoelasticity |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 9 - Flow Bifurcation |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 10 - Pulsatile Flow 1 |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 11 - Pulsatile Flow 2 |
Link |
NOC:An Introduction to Cardiovascular Fluid Mechanics |
Lecture 12 - Flow in Elastic Tubes |
Link |
NOC:Multiphase Microfluidics |
Lecture 1 - An Introduction |
Link |
NOC:Multiphase Microfluidics |
Lecture 2 - Interface and Surface Tension |
Link |
NOC:Multiphase Microfluidics |
Lecture 3 - Flow Regimes 1 |
Link |
NOC:Multiphase Microfluidics |
Lecture 4 - Flow Regimes 2 |
Link |
NOC:Multiphase Microfluidics |
Lecture 5 - Taylor Flow 1 |
Link |
NOC:Multiphase Microfluidics |
Lecture 6 - Taylor Flow 2 |
Link |
NOC:Multiphase Microfluidics |
Lecture 7 - Computational Techniques |
Link |
NOC:Multiphase Microfluidics |
Lecture 8 - Bubble and Droplet Generation |
Link |
NOC:Multiphase Microfluidics |
Lecture 9 - Interface and Surface tension 2 |
Link |
NOC:Multiphase Microfluidics |
Lecture 10 - Void Fraction and Pressure Drop |
Link |
NOC:Multiphase Microfluidics |
Lecture 11 - Liquid-Liquid Flow: Flow Regimes |
Link |
NOC:Multiphase Microfluidics |
Lecture 12 - Ideal annular Flow |
Link |
NOC:Multiphase Microfluidics |
Lecture 13 - Taylor Flow : Heat transfer 1 |
Link |
NOC:Multiphase Microfluidics |
Lecture 14 - Taylor Flow : Heat transfer 2 |
Link |
NOC:Multiphase Microfluidics |
Lecture 15 - Taylor Flow : Meat Transfer 1 |
Link |
NOC:Multiphase Microfluidics |
Lecture 16 - Taylor Flow : Meat Transfer 2 |
Link |
NOC:Multiphase Microfluidics |
Lecture 17 - Flow boiling in microchannels |
Link |
NOC:Multiphase Microfluidics |
Lecture 18 - Flow boiling in microchannels (Continued...) |
Link |
NOC:Multiphase Microfluidics |
Lecture 19 - Flow Measurement Techniques |
Link |
NOC:Multiphase Microfluidics |
Lecture 20 - Particle image Velocimetry |
Link |
NOC:Multiphase Microfluidics |
Lecture 21 - Inertial Microfluidics |
Link |
NOC:Multiphase Microfluidics |
Lecture 22 - Microfluidic applications |
Link |
NOC:Multiphase Microfluidics |
Lecture 23 - Microfluidic applications (Continued...) |
Link |
NOC:Multiphase Microfluidics |
Lecture 24 - Concluding Remarks |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 1 - Introduction to Multiphase flow Measurement Techniques |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 2 - Invasive and Non-invasive Techniques |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 3 - Hot Wire Anemometry |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 4 - Optical Fiber Probe |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 5 - Laser Doppler Anemometry (LDA) |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 6 - LDA Post Processing and Particle Image Velocimetry (PIV) |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 7 - PIV and Positron Emission Particle Tracking |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 8 - Radioactive Particle Tracking - I |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 9 - Radioactive Particle Tracking - II |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 10 - Capacitance Probe, Optical Fiber Probe and ECT |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 11 - Gamma-ray and X-ray Tomography, MRI |
Link |
NOC:Measurement Technique in Multiphase Flows |
Lecture 12 - Summary |
Link |
NOC:Multiphase Flows |
Lecture 1 - Multiphase flow introduction |
Link |
NOC:Multiphase Flows |
Lecture 2 - Fundamental definitions and terminology used in Multiphase - I |
Link |
NOC:Multiphase Flows |
Lecture 3 - Fundamental definitions and terminology used in Multiphase - II |
Link |
NOC:Multiphase Flows |
Lecture 4 - Flow Regime Map for Gas-Liquid System |
Link |
NOC:Multiphase Flows |
Lecture 5 - Flow Regime Map for Fluid-Solid System |
Link |
NOC:Multiphase Flows |
Lecture 6 - Pneumatic Conveying |
Link |
NOC:Multiphase Flows |
Lecture 7 - Momentum Equation through Reynolds Transport Theorem |
Link |
NOC:Multiphase Flows |
Lecture 8 - Lockhart Martinelli Correlation |
Link |
NOC:Multiphase Flows |
Lecture 9 - Pressure Drop Calculation for Homogeneous Flow |
Link |
NOC:Multiphase Flows |
Lecture 10 - Pressure Drop Calculation for Separated and Annular Flow Regime |
Link |
NOC:Multiphase Flows |
Lecture 11 - Lagrangian Tracking of Single Particle Under Different Forces |
Link |
NOC:Multiphase Flows |
Lecture 12 - Multiphase Interactions: Drag Force |
Link |
NOC:Multiphase Flows |
Lecture 13 - Multiphase Interactions: Multi-particle Drag, Virtual Mass Force, Basset Force and Lift Force |
Link |
NOC:Multiphase Flows |
Lecture 14 - Introduction to Multiphase Flow Modeling |
Link |
NOC:Multiphase Flows |
Lecture 15 - Algebraic Slip Method and Euler-Euler Method |
Link |
NOC:Multiphase Flows |
Lecture 16 - KTGF and Euler-Lagrangian Model |
Link |
NOC:Multiphase Flows |
Lecture 17 - Measurement Techniques: Velocity Measurement |
Link |
NOC:Multiphase Flows |
Lecture 18 - Measurement Techniques: Phase Fraction Measurement |
Link |
NOC:Multiphase Flows |
Lecture 19 - Bubble Column |
Link |
NOC:Multiphase Flows |
Lecture 20 - Packed Bed Reactor |
Link |
NOC:Multiphase Flows |
Lecture 21 - Fluidized Bed Reactor |
Link |
NOC:Multiphase Flows |
Lecture 22 - Summary |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 1 - Introduction to Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 2 - Ideal Chain Models |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 3 - Ideal and Real Chains |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 4 - Thermodynamics of Polymer Solutions - I |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 5 - Thermodynamics of Polymer Solutions - II |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 6 - Thermodynamics of Polymer Solutions - III |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 7 - Phase Behaviour of Polymer Solutions and Blends |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 8 - Phase Behaviour of Polymer Blends and Copolymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 9 - Determination of Polymer Molar Mass: Osmometry |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 10 - Determination of Polymer Molar Mass: Static Light Scattering - I |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 11 - Determination of Polymer Molar Mass: Static Light Scattering - II |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 12 - Determination of Polymer Molar Mass: Viscometry and GPC |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 13 - Branching: Hyperbranched Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 14 - Branching, Network Formation and Gelation |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 15 - Gelation and Swelling of Network Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 16 - Amorphous State of Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 17 - Crystalline State of Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 18 - Mechanical Properties of Polymers |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 19 - Viscoelasticity: Mechanical Models |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 20 - Viscoelasticity, Dynamic Mechanical Analysis and Rheology |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 21 - Rubber Elasticity |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 22 - Unentangled Polymer Dynamics |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 23 - Entangled Polymer Dynamics |
Link |
NOC:Introduction to Polymer Physics (IIT-G) |
Lecture 24 - Review |
Link |
NOC:Natural Gas Engineering |
Lecture 1 - Introduction to Natural Gas - I |
Link |
NOC:Natural Gas Engineering |
Lecture 2 - Introduction to Natural Gas - II |
Link |
NOC:Natural Gas Engineering |
Lecture 3 - Introduction to Natural Gas - III |
Link |
NOC:Natural Gas Engineering |
Lecture 4 - Properties of Natural Gas-I |
Link |
NOC:Natural Gas Engineering |
Lecture 5 - Properties of Natural Gas-II |
Link |
NOC:Natural Gas Engineering |
Lecture 6 - Properties of Reservoir |
Link |
NOC:Natural Gas Engineering |
Lecture 7 - Inflow Performance Relationship (IPR) - I |
Link |
NOC:Natural Gas Engineering |
Lecture 8 - Inflow Performance Relationship (IPR) - II |
Link |
NOC:Natural Gas Engineering |
Lecture 9 - Gas Well Testing |
Link |
NOC:Natural Gas Engineering |
Lecture 10 - Wellbore Performance Relationship (WPR) |
Link |
NOC:Natural Gas Engineering |
Lecture 11 - Choke Performance Relationship (CPR) |
Link |
NOC:Natural Gas Engineering |
Lecture 12 - Nodal Analysis |
Link |
NOC:Natural Gas Engineering |
Lecture 13 - Natural Gas Separation - I |
Link |
NOC:Natural Gas Engineering |
Lecture 14 - Natural Gas Separation - II |
Link |
NOC:Natural Gas Engineering |
Lecture 15 - Dehydration of Natural Gas |
Link |
NOC:Natural Gas Engineering |
Lecture 16 - Sweeting of Natural Gas |
Link |
NOC:Natural Gas Engineering |
Lecture 17 - Compressor Design |
Link |
NOC:Natural Gas Engineering |
Lecture 18 - Measurement of Natural Gas |
Link |
NOC:Natural Gas Engineering |
Lecture 19 - Transportation of Natural Gas - I |
Link |
NOC:Natural Gas Engineering |
Lecture 20 - Transportation of Natural Gas - II |
Link |
NOC:Natural Gas Engineering |
Lecture 21 - Unconventional production of Natural Gas |
Link |
NOC:Natural Gas Engineering |
Lecture 22 - Review: Concluding Remarks |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 1 - Introduction |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 2 - First law for closed systems |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 3 - First law for open systems |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 4 - Simple processes |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 5 - Processes involving liquids and ideal gases |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 6 - Temperature dependency of Cp in an ideal gas |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 7 - Efficiency of Heat engines and Statement of Second Law |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 8 - Entropy |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 9 - Lost Work |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 10 - Maxwell's Relations |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 11 - Thermodynamic Diagrams |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 12 - Thermodynamic Tables, Residual Properties |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 13 - Virial Equation of State |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 14 - Residual property relations from EoS |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 15 - Cubic Equation of State |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 16 - Cubic Equation of State |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 17 - Thermodynamic Tables |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 18 - Correlations for Liquids |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 19 - Process Involving Phase Changes |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 20 - Chemical potential |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 21 - Partial molar properties |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 22 - Examples |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 23 - Ideal Solutions |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 24 - Excess Properties |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 25 - Fugacity |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 26 - Calculation of Fugacity using EoS - Part 1 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 27 - Calculation of Fugacity using EoS - Part 2 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 28 - Calculation of Fugacity in Mixtures using Cubic EoS |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 29 - Fugacity in Liquids, Activity Coeffcient |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 30 - Models for Excess Gibbs free energy - Part 1 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 31 - Models for Excess Gibbs free energy - Part 2 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 32 - Vapor Liquid Equilibrium - Part 1 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 33 - Vapor Liquid Equilibrium - Part 2 |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 34 - Azeotropes |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 35 - Gamma/Phi Formulation |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 36 - LLE |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 37 - VLLE |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 38 - Enthalpy changes upon reaction |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 39 - Reaction coordinate |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 40 - Equilibrium constant |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 41 - Examples |
Link |
NOC:Chemical Engineering Thermodynamics |
Lecture 42 - Conclusion |
Link |
NOC:Mass Transfer Operations-I |
Lecture 1 - Introduction and Overview of Mass Transfer Operation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 2 - Molecular and Eddy Diffusion, Diffusion Velocities and Fluxes |
Link |
NOC:Mass Transfer Operations-I |
Lecture 3 - Fick's First and Second Law |
Link |
NOC:Mass Transfer Operations-I |
Lecture 4 - Steady State Molecular Diffusion in fluids under stagnant and laminar flow conditions |
Link |
NOC:Mass Transfer Operations-I |
Lecture 5 - Diffusion through variable cross-sectional area |
Link |
NOC:Mass Transfer Operations-I |
Lecture 6 - Gas Phase Diffusion Coefficient measurement |
Link |
NOC:Mass Transfer Operations-I |
Lecture 7 - Gas Phase Diffusion Coefficient prediction and liquid phase diffusion coefficient measurement and prediction |
Link |
NOC:Mass Transfer Operations-I |
Lecture 8 - Multicomponent diffusion and diffusivity in solids |
Link |
NOC:Mass Transfer Operations-I |
Lecture 9 - Mass transfer coefficient concept and classifications |
Link |
NOC:Mass Transfer Operations-I |
Lecture 10 - Dimensionless groups and correlations for convective mass transfer coefficients |
Link |
NOC:Mass Transfer Operations-I |
Lecture 11 - Mass transfer coefficient in laminar flow |
Link |
NOC:Mass Transfer Operations-I |
Lecture 12 - Boundary Layer Theory and mass transfer coefficients in turbulent flow |
Link |
NOC:Mass Transfer Operations-I |
Lecture 13 - Mass transfer theories |
Link |
NOC:Mass Transfer Operations-I |
Lecture 14 - Interphase mass transfer |
Link |
NOC:Mass Transfer Operations-I |
Lecture 15 - Interphase mass transfer and material balance for operating line |
Link |
NOC:Mass Transfer Operations-I |
Lecture 16 - Number of ideal stages in counter current operation: graphical and algebraic methods |
Link |
NOC:Mass Transfer Operations-I |
Lecture 17 - Introduction, classification, Sparged and agitated vessels design |
Link |
NOC:Mass Transfer Operations-I |
Lecture 18 - Gas dispersed: Tray tower |
Link |
NOC:Mass Transfer Operations-I |
Lecture 19 - Sieve Tray |
Link |
NOC:Mass Transfer Operations-I |
Lecture 20 - Liquid dispersed: Venture scrubber, wetted wall column, Packed tower |
Link |
NOC:Mass Transfer Operations-I |
Lecture 21 - Introduction to absorption, Equilibrium in gas-liquid system, and minimum liquid rate |
Link |
NOC:Mass Transfer Operations-I |
Lecture 22 - Design of packed column absorber based on the Individual Mass Transfer Coefficient |
Link |
NOC:Mass Transfer Operations-I |
Lecture 23 - Design of packed column absorber based on the Overall Mass Transfer Coefficient |
Link |
NOC:Mass Transfer Operations-I |
Lecture 24 - Height Equivalent to a Theoretical Plate (HETP), Design of packed column absorber for dilute and concentrated gases |
Link |
NOC:Mass Transfer Operations-I |
Lecture 25 - Absorption in plate column: Method of McCabe and Thiele-graphical determination of ideal trays and Introduction to multicomponent absorption |
Link |
NOC:Mass Transfer Operations-I |
Lecture 26 - Introduction to distillation, binary equilibrium diagrams and concept of relative volatility |
Link |
NOC:Mass Transfer Operations-I |
Lecture 27 - Distillation in non-ideal systems and concept of enthalpy-concentration diagram |
Link |
NOC:Mass Transfer Operations-I |
Lecture 28 - Flash distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 29 - Batch and steam distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 30 - Continuous multistate fractionation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 31 - Number of trays by McCabe and Thiele for distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 32 - Pinch Points and minimum reflux |
Link |
NOC:Mass Transfer Operations-I |
Lecture 33 - Reflux below its bubble point: Sub-cooled reflux and use of open steam |
Link |
NOC:Mass Transfer Operations-I |
Lecture 34 - Multiple feeds, multiple product withdrawal or side streams |
Link |
NOC:Mass Transfer Operations-I |
Lecture 35 - Multistage batch distillation with reflux |
Link |
NOC:Mass Transfer Operations-I |
Lecture 36 - The Ponchon-Savarit method |
Link |
NOC:Mass Transfer Operations-I |
Lecture 37 - The Ponchon-Savarit method |
Link |
NOC:Mass Transfer Operations-I |
Lecture 38 - Packed Distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 39 - Introduction to multicomponent distillation and multicomponent flash distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 40 - Minimum stages and minimum reflux in multicomponent distillation |
Link |
NOC:Mass Transfer Operations-I |
Lecture 41 - Multicomponent batch distillation |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 1 - Introduction and Basic Concepts |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 2 - Classification of Non-Newtonian Fluids |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 3 - Mathematical Models for Non-Newtonian Fluids |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 4 - Viscoelastic Non-Newtonian Fluids |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 5 - Capillary Viscometers: Sources of Errors and Correction Methods |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 6 - Rotational Viscometers |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 7 - Capillary Viscometers - Errors and Corrections II |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 8 - Equation of Change for Non-Isothermal Systems |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 9 - Rotational Viscometers - II |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 10 - Rotational Viscometers - III |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 11 - Transition from Laminar to Turbulent Flow in Pipes for GNF |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 12 - Equations of Change for Isothermal Systems |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 13 - Equations of Change for Non-Isothermal Systems |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 14 - Power-law Fluids Flow in Concentric Annulus |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 15 - Power-law and Ellis Model Fluids Flow Through Pipes |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 16 - Bingham Plastic Fluids Flow through Pipes |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 17 - Herschel Bulkley Fluids Flow through Pipes |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 18 - Transition and Turbulent Flow of GNF in Pipes - I |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 19 - Transition and Turbulent Flow of GNF in Pipes - II |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 20 - Laminar flow of GNFs between Parallel Plates and along Inclined Surface |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 21 - Laminar flow of GNFs along Inclined Surface and Concentric Annulus |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 22 - Flow of Non-Newtonian Fluids through Packed Beds |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 23 - Dispersion in Packed Beds: Non-Newtonian Effects |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 24 - Liquid-Solid Fluidization by Power-law Liquids |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 25 - Free Convection between Two Vertical Plates |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 26 - Viscous Heat Generation |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 27 - Temperature distribution in fluids confined between co-axial cylinders |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 28 - Temperature distribution for FDF of Newtonian fluids in tubes |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 29 - Heat Transfer Combined with Chemical Reactions |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 30 - Transpiration Cooling |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 31 - Basics of MT; Diffusion Through Stagnant Gas Film |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 32 - Non-Isothermal Diffusive MT and Forced Convective MT |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 33 - Simultaneous Heat and Mass Transfer |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 34 - Mass Transfer Combined with Chemical Reactions |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 35 - Quasi-Steady Analysis of Simultaneous HT, MT and Chemical Reaction |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 36 - Quasi-Steady Analysis of Simultaneous HT and MT - I |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 37 - Quasi-Steady Analysis of Simultaneous HT and MT - II |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 38 - Quasi-Steady Analysis of Simultaneous HT and MT - III |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 39 - Momentum and Thermal Boundary Layer Flows |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 40 - Momentum Boundary Layer Thickness of Non-Newtonian Fluids |
Link |
NOC:Transport Phenomena of Non-Newtonian Fluids |
Lecture 41 - Thermal and Concentration Boundary Layer Thickness of Non-Newtonian Fluids |
Link |
NOC:Fluid Flow Operations |
Lecture 1 - Introduction |
Link |
NOC:Fluid Flow Operations |
Lecture 2 - Characteristics of fluid (Continued...) |
Link |
NOC:Fluid Flow Operations |
Lecture 3 - Fluid Statics |
Link |
NOC:Fluid Flow Operations |
Lecture 4 - Fluid Statics (Continued...) |
Link |
NOC:Fluid Flow Operations |
Lecture 5 - Fundamentals of flow - Part 1 |
Link |
NOC:Fluid Flow Operations |
Lecture 6 - Fundamentals of flow - Part 2 |
Link |
NOC:Fluid Flow Operations |
Lecture 7 - One dimensional flow - Part 1 |
Link |
NOC:Fluid Flow Operations |
Lecture 8 - One dimensional flow - Part 2 |
Link |
NOC:Fluid Flow Operations |
Lecture 9 - One dimensional flow - Part 3 |
Link |
NOC:Fluid Flow Operations |
Lecture 10 - Flow of Viscous fluid - Introduction |
Link |
NOC:Fluid Flow Operations |
Lecture 11 - Velocity distribution in laminar flow |
Link |
NOC:Fluid Flow Operations |
Lecture 12 - Velocity distribution in turbulent flow |
Link |
NOC:Fluid Flow Operations |
Lecture 13 - Boundary layer theory |
Link |
NOC:Fluid Flow Operations |
Lecture 14 - Theory of lubrication |
Link |
NOC:Fluid Flow Operations |
Lecture 15 - Frictional resistance |
Link |
NOC:Fluid Flow Operations |
Lecture 16 - Losses in gematric change |
Link |
NOC:Fluid Flow Operations |
Lecture 17 - Losses in geometric change (Continued...) |
Link |
NOC:Fluid Flow Operations |
Lecture 18 - Flow Velocity and Optimum Shape |
Link |
NOC:Fluid Flow Operations |
Lecture 19 - Equation of Energy and Discharge of Water Channel |
Link |
NOC:Fluid Flow Operations |
Lecture 20 - Drag |
Link |
NOC:Fluid Flow Operations |
Lecture 21 - Lift and Cavitation |
Link |
NOC:Fluid Flow Operations |
Lecture 22 - Dimensional Analysis |
Link |
NOC:Fluid Flow Operations |
Lecture 23 - Dimensional Analysis: Buckingham’s PI Theorem |
Link |
NOC:Fluid Flow Operations |
Lecture 24 - Law of Similarity and Significant Dimensionless Number |
Link |
NOC:Fluid Flow Operations |
Lecture 25 - Compressible Flow - Part 1 |
Link |
NOC:Fluid Flow Operations |
Lecture 26 - Compressible Flow - Part 2 |
Link |
NOC:Fluid Flow Operations |
Lecture 27 - Measurement of Flow - Part 1 |
Link |
NOC:Fluid Flow Operations |
Lecture 28 - Measurement of Flow - Part 2 |
Link |
NOC:Fluid Flow Operations |
Lecture 29 - Measurement of Flow - Part 3 |
Link |
NOC:Fluid Flow Operations |
Lecture 30 - Introduction to multiphase flow |
Link |
NOC:Fluid Flow Operations |
Lecture 31 - Hydrodynamics in multiphase flow |
Link |
NOC:Fluid Flow Operations |
Lecture 32 - Hydrodynamics in multiphase flow (Continued...) |
Link |
NOC:Fluid Flow Operations |
Lecture 33 - Applications of multiphase flow |
Link |
NOC:Chemical Process Intensification |
Lecture 1 - History, Philosophy and Concept |
Link |
NOC:Chemical Process Intensification |
Lecture 2 - Principle Features |
Link |
NOC:Chemical Process Intensification |
Lecture 3 - Strategies and domain based techniques |
Link |
NOC:Chemical Process Intensification |
Lecture 4 - Intensification by fluid flow process |
Link |
NOC:Chemical Process Intensification |
Lecture 5 - Mechanism of Intensification by mixing |
Link |
NOC:Chemical Process Intensification |
Lecture 6 - Intensification in Reactive system |
Link |
NOC:Chemical Process Intensification |
Lecture 7 - Problems leading to sustainable development |
Link |
NOC:Chemical Process Intensification |
Lecture 8 - Concept, Issues and Challenges |
Link |
NOC:Chemical Process Intensification |
Lecture 9 - Strategies in process design |
Link |
NOC:Chemical Process Intensification |
Lecture 10 - Scales and stages of process intensification |
Link |
NOC:Chemical Process Intensification |
Lecture 11 - Methods and Tools for Achieving sustainable design |
Link |
NOC:Chemical Process Intensification |
Lecture 12 - Multi-level Computer aided tools |
Link |
NOC:Chemical Process Intensification |
Lecture 13 - Introduction on Stochastic Optimization |
Link |
NOC:Chemical Process Intensification |
Lecture 14 - Optimization Algorithms |
Link |
NOC:Chemical Process Intensification |
Lecture 15 - Applications of Optimization Algorithms |
Link |
NOC:Chemical Process Intensification |
Lecture 16 - Introduction and Mechanism of Cavitation-based PI |
Link |
NOC:Chemical Process Intensification |
Lecture 17 - Cavitational Reactor Configurations and activity |
Link |
NOC:Chemical Process Intensification |
Lecture 18 - Parametric effects on cavitation |
Link |
NOC:Chemical Process Intensification |
Lecture 19 - Introduction of monolith reactor |
Link |
NOC:Chemical Process Intensification |
Lecture 20 - Preparation of monolithic catalyst |
Link |
NOC:Chemical Process Intensification |
Lecture 21 - Application of monolithic catalyst |
Link |
NOC:Chemical Process Intensification |
Lecture 22 - Hydrodynamics, transport of monolithic reactor |
Link |
NOC:Chemical Process Intensification |
Lecture 23 - Overview of interfacial area based processes |
Link |
NOC:Chemical Process Intensification |
Lecture 24 - Ejector induced downflow system for PI |
Link |
NOC:Chemical Process Intensification |
Lecture 25 - Hydrodynamics and transport in downflow system |
Link |
NOC:Chemical Process Intensification |
Lecture 26 - Introduction and Principles |
Link |
NOC:Chemical Process Intensification |
Lecture 27 - Types of Intensified Distillation Units |
Link |
NOC:Chemical Process Intensification |
Lecture 28 - Design of membrane-assisted distillation |
Link |
NOC:Chemical Process Intensification |
Lecture 29 - Introduction and Principles |
Link |
NOC:Chemical Process Intensification |
Lecture 30 - Supercritical extraction for process intensification |
Link |
NOC:Chemical Process Intensification |
Lecture 31 - Introduction to membrane and its principles |
Link |
NOC:Chemical Process Intensification |
Lecture 32 - Membrane engineering in process intensification |
Link |
NOC:Chemical Process Intensification |
Lecture 33 - Introduction to microprocess technology |
Link |
NOC:Chemical Process Intensification |
Lecture 34 - Process Intensification by Microreactors |
Link |
NOC:Chemical Process Intensification |
Lecture 35 - Hydrodynamics and transport in microchannel based microreactor |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 1 - Introduction and Overview on Reaction Engineering |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 2 - Kinetics of Homogeneous Reactions |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 3 - Kinetic Model and Temperature Dependency |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 4 - Introduction and Stoichiometry for the Batch System |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 5 - Stoichiometry for Constant Volume Flow and Variable Volume Batch Systems |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 6 - Stoichiometry for Variable Volume Flow System |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 7 - Analysis of Batch Reactor Kinetic Data |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 8 - Intregal Method of Analysis of Batch Reactor Data - Part 1 |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 9 - Intregal Method of Analysis of Batch Reactor Data - Part 2 |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 10 - Differential Method of Analysis and Variable Volume Batch Reactor Data |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 11 - Introduction and Ideal Batch Reactor Design |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 12 - Ideal Mixed Flow Reactor Design |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 13 - Ideal Plug Flow Reactor Design |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 14 - Size Comparisn of Single and Multiple Reactors |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 15 - Size Comaprison Multiple Reactors |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 16 - Recycle and Autocatalytic Reactors |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 17 - Design for Parallel Reactions |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 18 - Design for Series Reactions |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 19 - Design for Series-Parallel Reactions |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 20 - Denbigh Reactions and Their Special Cases |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 21 - Heats of Reaction and Equilibrium Conversion from Thermodynamics |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 22 - General Graphical Reactor Design Procedure |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 23 - Material and Energy Balances in Batch Reactor |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 24 - Optimum Temperature Progression in Batch Reactor |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 25 - Material and Energy Balances in Flug Flow and Mixed Flow Reactors |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 26 - Ideal and Non-Ideal Mixed Flow Reactor Design and Multiple Steady States |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 27 - Non-Ideal Reactors and Residence Time Distribution |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 28 - RTD Measurement and Moments of RTD |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 29 - RTD in Ideal Reactors |
Link |
NOC:Chemical Reaction Engineering-I |
Lecture 30 - Reactor Modeling using the RTD |
Link |
NOC:Mass Transfer Operations-II |
Lecture 1 - Basic concepts, Adiabatic saturation temperature |
Link |
NOC:Mass Transfer Operations-II |
Lecture 2 - Design calculations of cooling tower |
Link |
NOC:Mass Transfer Operations-II |
Lecture 3 - Design of cooling tower |
Link |
NOC:Mass Transfer Operations-II |
Lecture 4 - Design of cooling tower |
Link |
NOC:Mass Transfer Operations-II |
Lecture 5 - Air conditioning, Example problems on dehumidification |
Link |
NOC:Mass Transfer Operations-II |
Lecture 6 - Mechanism of drying and drying equilibria, drying rate curve |
Link |
NOC:Mass Transfer Operations-II |
Lecture 7 - Drying: rate of drying for batch dryers |
Link |
NOC:Mass Transfer Operations-II |
Lecture 8 - Drying: rate of drying for continuous dryers |
Link |
NOC:Mass Transfer Operations-II |
Lecture 9 - Drying time calculation from drying rate curve |
Link |
NOC:Mass Transfer Operations-II |
Lecture 10 - Introduction to liquid-liquid extraction, liquid-liquid equilibria |
Link |
NOC:Mass Transfer Operations-II |
Lecture 11 - Effect of temperature on LLE and Design of single stage extraction |
Link |
NOC:Mass Transfer Operations-II |
Lecture 12 - Design Calculation of Multistage Operation |
Link |
NOC:Mass Transfer Operations-II |
Lecture 13 - Design calculation of multistage cross-current extraction |
Link |
NOC:Mass Transfer Operations-II |
Lecture 14 - Design calculation of multistage counter-current extraction, Selection of extractors |
Link |
NOC:Mass Transfer Operations-II |
Lecture 15 - Leaching: single stage operation |
Link |
NOC:Mass Transfer Operations-II |
Lecture 16 - Leaching: multistage operation |
Link |
NOC:Mass Transfer Operations-II |
Lecture 17 - Supercritical Fluid Extraction, equipmet for leaching |
Link |
NOC:Mass Transfer Operations-II |
Lecture 18 - Fundamentals of membrane separation processes |
Link |
NOC:Mass Transfer Operations-II |
Lecture 19 - Manufacturing of membranes,advantages and limitations |
Link |
NOC:Mass Transfer Operations-II |
Lecture 20 - Various models and applications: design aspects |
Link |
NOC:Mass Transfer Operations-II |
Lecture 21 - Various models and applications: design aspects |
Link |
NOC:Mass Transfer Operations-II |
Lecture 22 - Electric field enhanced membrane separation processes |
Link |
NOC:Mass Transfer Operations-II |
Lecture 23 - Micellar-enhanced ultrafiltration |
Link |
NOC:Mass Transfer Operations-II |
Lecture 24 - Adsorption: types and nature, isotherm |
Link |
NOC:Mass Transfer Operations-II |
Lecture 25 - Stage wise and continuous adsorption |
Link |
NOC:Mass Transfer Operations-II |
Lecture 26 - Fluidized bed and teeter bed |
Link |
NOC:Mass Transfer Operations-II |
Lecture 27 - Unsteady state fixed bed adsorbers, ion exchange |
Link |
NOC:Mass Transfer Operations-II |
Lecture 28 - Crystallization, types of crystal geometry |
Link |
NOC:Mass Transfer Operations-II |
Lecture 29 - Solid-liquid phase equilibrium, Theory of crystallization |
Link |
NOC:Mass Transfer Operations-II |
Lecture 30 - Design of crystallizer, crystallization equipment |
Link |
NOC:Mass Transfer Operations-II |
Lecture 31 - Concluding remarks - Part 1 |
Link |
NOC:Mass Transfer Operations-II |
Lecture 32 - Concluding remarks - Part 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 1 - Introduction of Particulate Solids |
Link |
NOC:Mechanical Unit Operations |
Lecture 2 - Particle Size |
Link |
NOC:Mechanical Unit Operations |
Lecture 3 - Particle Shape and Density |
Link |
NOC:Mechanical Unit Operations |
Lecture 4 - Screening |
Link |
NOC:Mechanical Unit Operations |
Lecture 5 - Size Analysis by Screening |
Link |
NOC:Mechanical Unit Operations |
Lecture 6 - Screening Equipment, Effectiveness and Capacity |
Link |
NOC:Mechanical Unit Operations |
Lecture 7 - Methods of Size Reduction |
Link |
NOC:Mechanical Unit Operations |
Lecture 8 - Equipment for Size Reduction - Crushers |
Link |
NOC:Mechanical Unit Operations |
Lecture 9 - Equipment for Size Reduction - Gridners |
Link |
NOC:Mechanical Unit Operations |
Lecture 10 - Equipment for Size Reduction - Ultrafine Grinders and Cutting Machines |
Link |
NOC:Mechanical Unit Operations |
Lecture 11 - Storage of Bulk Solids |
Link |
NOC:Mechanical Unit Operations |
Lecture 12 - Solids Flow Out and their Flow Patterns |
Link |
NOC:Mechanical Unit Operations |
Lecture 13 - Conveying of Bulk Solids |
Link |
NOC:Mechanical Unit Operations |
Lecture 14 - Size Enlargement Methods |
Link |
NOC:Mechanical Unit Operations |
Lecture 15 - Size Enlargement Equipment - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 16 - Size Enlargement Equipment - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 17 - Flow past Immersed Solid Objects |
Link |
NOC:Mechanical Unit Operations |
Lecture 18 - Motion of Particles through Fluids - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 19 - Motion of Particles through Fluids - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 20 - Motion of Particles through Fluids - 3 |
Link |
NOC:Mechanical Unit Operations |
Lecture 21 - Flow through Beds of Solids - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 22 - Flow through Beds of Solids - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 23 - Flow through Fluidized Beds - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 24 - Flow through Fluidized Beds - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 25 - Filtration |
Link |
NOC:Mechanical Unit Operations |
Lecture 26 - Principles of Cake Filtration - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 27 - Principles of Cake Filtration - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 28 - Filtration Equipment |
Link |
NOC:Mechanical Unit Operations |
Lecture 29 - Cross Flow Filtration - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 30 - Cross Flow Filtration - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 31 - Gravity Sedimentation - Classifiers |
Link |
NOC:Mechanical Unit Operations |
Lecture 32 - Gravity Sedimentation - Design of Thickeners - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 33 - Gravity Sedimentation - Design of Thickeners - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 34 - Centrifugal Separations - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 35 - Centrifugal Separations - 2 |
Link |
NOC:Mechanical Unit Operations |
Lecture 36 - Floatation - 1 |
Link |
NOC:Mechanical Unit Operations |
Lecture 37 - Floatation - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 1 - Introduction of Phase Equilibrium |
Link |
NOC:Advanced Thermodynamics |
Lecture 2 - Classical Thermodynamics of Phase Equilibria - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 3 - Classical Thermodynamics of Phase Equilibria - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 4 - Thermodynamic Properties from Volumetric Data |
Link |
NOC:Advanced Thermodynamics |
Lecture 5 - Fugacity from Volumetric Data - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 6 - Fugacity from Volumetric Data - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 7 - Intermolecular Forces and Non-Ideal Behaviour |
Link |
NOC:Advanced Thermodynamics |
Lecture 8 - Intermolecular Forces-Potential Energy Functions |
Link |
NOC:Advanced Thermodynamics |
Lecture 9 - Molecular Theory of Corresponding States - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 10 - Molecular Theory of Corresponding States - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 11 - Intermolecular Potential and EoS |
Link |
NOC:Advanced Thermodynamics |
Lecture 12 - Virial Coefficients from Potential Functions |
Link |
NOC:Advanced Thermodynamics |
Lecture 13 - Virial Coefficients from Corresponding States Theory |
Link |
NOC:Advanced Thermodynamics |
Lecture 14 - Fugacities in Gaseous Mixtures - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 15 - Fugacities in Gaseous Mixtures - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 16 - Fugacities in Gaseous Mixtures - 3 |
Link |
NOC:Advanced Thermodynamics |
Lecture 17 - Liquid Mixtures and Excess Functions |
Link |
NOC:Advanced Thermodynamics |
Lecture 18 - Excess Functions and Activity Coefficients |
Link |
NOC:Advanced Thermodynamics |
Lecture 19 - Activity Coefficients and Thermodynamic Consistency |
Link |
NOC:Advanced Thermodynamics |
Lecture 20 - Models for Excess Gibbs Energy - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 21 - Models for Excess Gibbs Energy - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 22 - Models for Excess Gibbs Energy - 3 |
Link |
NOC:Advanced Thermodynamics |
Lecture 23 - Vapour-Liquid Equilibrium - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 24 - Vapour-Liquid Equilibrium - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 25 - Vapour-Liquid Equilibrium - 3 |
Link |
NOC:Advanced Thermodynamics |
Lecture 26 - Liquid-Liquid Equilibrium - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 27 - Liquid-Liquid Equilibrium - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 28 - Vapour-Liquid-Liquid Equilibrium - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 29 - Vapour-Liquid-Liquid Equilibrium - 2 |
Link |
NOC:Advanced Thermodynamics |
Lecture 30 - Solid-Liquid Equilibrium - 1 |
Link |
NOC:Advanced Thermodynamics |
Lecture 31 - Solid-Liquid Equilibrium - 2 |
Link |
NOC:Membrane Technology |
Lecture 1 - Separation Processes, Historical Development, Definition and Types of Membranes |
Link |
NOC:Membrane Technology |
Lecture 2 - Membrane Processes and Classifications, Advantages, Disadvantages, Applications |
Link |
NOC:Membrane Technology |
Lecture 3 - Polymer Basics, Polymers used in Membrane Preparation and their Properties |
Link |
NOC:Membrane Technology |
Lecture 4 - Inorganic Materials for Membrane Preparation, their Advantages and Disadvantages |
Link |
NOC:Membrane Technology |
Lecture 5 - Membrane Modules and Selection, Flow Types |
Link |
NOC:Membrane Technology |
Lecture 6 - Preparation of Synthetic Membrane, Phase Inversion Membranes |
Link |
NOC:Membrane Technology |
Lecture 7 - Composite membranes: Interfacial polymerization, dip-coating, plasma polymerization |
Link |
NOC:Membrane Technology |
Lecture 8 - Inorganic membranes: Sol-Gel process, ceramic membrane preparation, membrane modification |
Link |
NOC:Membrane Technology |
Lecture 9 - Porous and non-porous membranes, characterization of porous membranes and MF membrane |
Link |
NOC:Membrane Technology |
Lecture 10 - MF membrane characterization: Bubble point,Mercury intrusion, Permeability method |
Link |
NOC:Membrane Technology |
Lecture 11 - UF membrane characterization: Gas adsorption-desorption, Thermoporometry, MWCO method |
Link |
NOC:Membrane Technology |
Lecture 12 - Passive transport, active transport, description of transport process |
Link |
NOC:Membrane Technology |
Lecture 13 - Transport through porous membrane and nonporus membrane |
Link |
NOC:Membrane Technology |
Lecture 14 - Concept of osmosis and reverse osmosis, thermodynamic analysis |
Link |
NOC:Membrane Technology |
Lecture 15 - Revision of concepts and fundaments |
Link |
NOC:Membrane Technology |
Lecture 16 - HP and LP RO, membrane materials, modules, models for RO transport |
Link |
NOC:Membrane Technology |
Lecture 17 - Advantages of RO, fouling, RO applications, Pressure retarded osmosis |
Link |
NOC:Membrane Technology |
Lecture 18 - Nanofiltration basics, transport mechanism, fouling model and applications |
Link |
NOC:Membrane Technology |
Lecture 19 - Basic principles of UF, membranes and modules, UF configurations |
Link |
NOC:Membrane Technology |
Lecture 20 - Models for UF transport, mass transfer coefficient, membrane rejection and sieving coefficient |
Link |
NOC:Membrane Technology |
Lecture 21 - Factors affecting UF performance, fouling and permeate flux enhancement, UF applications1 |
Link |
NOC:Membrane Technology |
Lecture 22 - Micellar-enhanced UF, affinity UF, UF based bioseparation |
Link |
NOC:Membrane Technology |
Lecture 23 - Basic principles, advantages of MF, cross-flow and dead-end MF, membranes and modules |
Link |
NOC:Membrane Technology |
Lecture 24 - Models for MF transport, plugging and throughput, fouling in MF, MF applications |
Link |
NOC:Membrane Technology |
Lecture 25 - Problems and solutions based on RO and MF |
Link |
NOC:Membrane Technology |
Lecture 26 - Problems and solutions based on UF |
Link |
NOC:Membrane Technology |
Lecture 27 - Dialysis, membranes and modules, mass transport in dialysis, diffusion analysis, applications |
Link |
NOC:Membrane Technology |
Lecture 28 - Ion-exchange membranes, ED process, energy requirement, applications, reverse ED |
Link |
NOC:Membrane Technology |
Lecture 29 - PV principle, advantages, mass transfer and applications, hybrid distillation/PV |
Link |
NOC:Membrane Technology |
Lecture 30 - Problems and solutions based on ED and PV |
Link |
NOC:Membrane Technology |
Lecture 31 - Concept, types of LM, mechanism of mass transfer in LM, choice of solvent and carrier, applications |
Link |
NOC:Membrane Technology |
Lecture 32 - Basic principle of gas separation, transport mechanism, factors affecting gas separation, applications |
Link |
NOC:Membrane Technology |
Lecture 33 - Basic principle of MD, mechanism, process parameters, membranes, applications |
Link |
NOC:Membrane Technology |
Lecture 34 - Mechanism, coupled transport, carrier agent, active and passive transport, applications |
Link |
NOC:Membrane Technology |
Lecture 35 - Gas-liquid and liquid-liquid contactors, membrane reactors and bioreactors, PEM hydrogen fuel cell |
Link |
NOC:Membrane Technology |
Lecture 36 - Perstraction, membrane chromatography and controlled drug delivery |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 1 - Introduction to Optimization |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 2 - Linear Regression |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 3 - Multiple, Polynomial and General Linear Least Square Regression |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 4 - Nonlinear Regression |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 5 - Regression : MATLAB Implementation |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 6 - Teaching Learning Based Optimization |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 7 - Implementation of TLBO in MATLAB |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 8 - Supplementary: Preliminary Statistical analysis for metaheuristic techniques |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 9 - Supplementary: Preliminary Statistical analysis - MATLAB implementation |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 10 - Particle Swarm Optimization |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 11 - Implementation of Particle Swarm Optimization using MATLAB |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 12 - Differential Evolution |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 13 - Implementation of Differential Evolution using MATLAB |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 14 - Binary Coded Genetic Algorithm |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 15 - Real Coded Genetic Algorithm |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 16 - Implementation of Real Coded Genetic Algorithm using MATLAB |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 17 - Artificial Bee Colony Algorithm |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 18 - Working of Artificial Bee Colony Algorithm |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 19 - Implementation of Artificial Bee Colony using MATLAB |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 20 - Comparison of Variation Operators and Survival Strategies |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 21 - Black-Box Optimization Problems |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 22 - Constraint-Handling in Metaheuristic Techniques |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 23 - Case Study: Production planning |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 24 - Case Study: Production planning MATLAB Implementation |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 25 - Parallelization and Vectorization of Fitness Function |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 26 - Constraint-Handling using Correction Approach |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 27 - MATLAB inbuilt functions: Linear and Mixed Integer Linear Programming |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 28 - MATLAB inbuilt functions: Nonlinear and Mixed Integer Nonlinear Programming |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 29 - MATLAB Optimization Tool: Options, Output Function, Vectorization, Parallelization |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 30 - MATLAB inbuilt functions: Multi-objective Optimization |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 31 - Simplex Method for LP |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 32 - Branch and Bound Method for MILP |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 33 - MILP formulation of Production Planning Problem |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 34 - Generalized Algebraic Modelling System |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 35 - Solution of Production Planning Problem using GAMS and NEOS, MIRO |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 36 - IBM ILOG CPLEX Optimization Studio |
Link |
NOC:Computer Aided Applied Single Objective Optimization |
Lecture 37 - Constraint Programming Applications in IBM ILOG CPLEX Optimization Studio |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 1 - Definition, History, Role of Chemical Engineer |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 2 - Basic Features of Chemical Process |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 3 - Unit systems and dimensions |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 4 - Variables and Properties of Material in System |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 5 - Pressure and Temperature of Flow Process |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 6 - Rate of Process |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 7 - Principles of material balance and calculation |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 8 - Material Balances on Processes with Recycle and Bypass |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 9 - Material balances on reactive processes |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 10 - Material balances on combustion reactions |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 11 - State Equation of Ideal Gas and Calculation |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 12 - State Equation of non-Ideal Gas and Calculation |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 13 - Phase equilibrium |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 14 - Equilibrium Laws, Humidity and Saturation |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 15 - Humidity, Saturation Psychrometric chart |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 16 - Process of phase change: Condensation and vaporization |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 17 - Principles of Energy |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 18 - Laws and properties of thermodynamics |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 19 - Standard Heat of Formation |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 20 - The mechanical energy balance |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 21 - Enthalpy balances without reaction |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 22 - Energy balance with multiplle streams without reaction |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 23 - Energy balance on heat of solution |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 24 - Energy balance with heat of reaction |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 25 - Energy balance with heat of reaction (Continued...) |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 26 - Energy balance with heat of combustion |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 27 - Material balance of transient process |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 28 - Unsteady state energy balance |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 29 - Least Square Method Linear equation fitting |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 30 - Non-linear algebraic equation system |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 31 - Numerical Integration |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 32 - Process Degrees of Freedom |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 33 - Process Flowsheeting and codes |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 34 - Case Study: Cumene Production |
Link |
NOC:Basic Principles and Calculations in Chemical Engineering |
Lecture 35 - Case Study: Cumene Production (Continued...) |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 1 - Solar Energy: An overview of thermal applications |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 2 - Solar radiation |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 3 - Practice problems - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 4 - Practice problems - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 5 - Non-concentrating solar collectors - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 6 - Non-concentrating solar collectors - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 7 - Non-concentrating solar collectors - Part III |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 8 - Practice problems - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 9 - Practice problems - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 10 - Practice problems - Part III |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 11 - Parabolic solar collectors |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 12 - Practice problems |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 13 - Thermal energy storage systems - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 14 - Thermal energy storage systems - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 15 - Solar energy utilization methods |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 16 - Classification of energy resources |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 17 - Broad classification and compositional analysis |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 18 - Characteristics and properties of biomass |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 19 - Properties and structural components of biomass |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 20 - Biomass residues and energy conversion routes |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 21 - Utilisation of biomass through bio-chemical and thermo-chemical routes |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 22 - Conversion mechanism of biomass to biogas and its properties |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 23 - Classification of biogas plants |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 24 - Practice problems - I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 25 - Practice problems - II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 26 - Practice problems - III |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 27 - Bioconversion of substrates into alcohol |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 28 - Thermo-chemical conversion, torrefaction and combustion processes |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 29 - Thermo-chemical conversion of biomass to solid, liquid and gaseous fuels |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 30 - Gasification process |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 31 - Thermo-chemical conversion processes: pyrolysis, liquefaction and conversion processes |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 32 - Practice problems - I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 33 - Practice problems - II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 34 - Turbine terms, types and theories - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 35 - Turbine terms, types and theories - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 36 - Characteristics and Power Generation from Wind Energy - Part I |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 37 - Characteristics and Power Generation from Wind Energy - Part II |
Link |
NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems |
Lecture 38 - Practice problems |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 1 - Energy and Environment scenario |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 2 - Need for biomass based industries |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 3 - Biomass basics |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 4 - Dedicated energy crops |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 5 - Oil cropns and microalgae |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 6 - Enhancing biomass properties |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 7 - Basic concepts and types |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 8 - Feedstocks and properties |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 9 - Economics and LCA |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 10 - Barriers and Types |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 11 - Dilute acid, alkali, ozone |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 12 - Hybrid methods |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 13 - Physical Processes |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 14 - Gasification and Pyrolysis |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 15 - Products and Commercial Success Stories |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 16 - Types, fundamentals, equipments, applications |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 17 - Details of various processes |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 18 - Products and Commercial Success Stories |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 19 - Diesel from vegetable oils, microalgae and syngas |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 20 - Transesterification; FT process, catalysts |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 21 - Biodiesel purification, fuel properties |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 22 - Biooil and biochar production, reactors |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 23 - Factors affecting biooil, biochar production, fuel properties characterization |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 24 - Biooil upgradation technologies |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 25 - Microorganisms, current industrial ethanol production technology |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 26 - Cellulase production, SSF and CBP |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 27 - ABE fermentation pathway and kinetics, product recovery technologies |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 28 - Biohydrogen production, metabolics, microorganisms |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 29 - Biogas technology, fermenter designs, biogas purification |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 30 - Methanol production and utilization |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 31 - Biomass as feedstock for synthetic organic chemicals, lactic acid, polylactic acid |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 32 - Succinic acid, propionic acid, acetic acid, butyric acid |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 33 - 1,3-propanediol, 2,3-butanedioil, PHA |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 34 - Concept, lignocellulosic biorefinery |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 35 - Aquaculture and algal biorefinery, waste biorefinery |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 36 - Techno-economic evaluation |
Link |
NOC:Biomass Conversion and Biorefinery |
Lecture 37 - Life-cycle assessment |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 1 - Significance of software with example - Simulation on pen and paper vs simulation on Aspen Plus |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 2 - Understanding Resources and My Exchange, Start using Aspen Plus |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 3 - Overview of setting up of property environment |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 4 - Using Model Pallete - Mixers/Splitters, Separators |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 5 - Using Model Pallete - Exchangers |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 6 - Using Model Pallete - Columns |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 7 - Using Model Palette - Reactors |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 8 - Using Model Palette - Pressure Changers |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 9 - Example: Hydrocarbon Treatment - Part 1 |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 10 - Example: Hydrocarbon Treatment - Part 2 |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 11 - Setup, Components |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 12 - Property Methods |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 13 - Property Methods and Propeety Sets with example |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 14 - Analysis tools (Pure Components and Binary mixtures) |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 15 - Analysis tools (Ternary mixtures), Data and Regression (Part 1) |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 16 - Data and Regression (Part 2), Property Estimation |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 17 - Practice problems on pure components |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 18 - Practice problems on binary mixtures |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 19 - Miscellaneous practice problems and case studies |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 20 - Model Analysis Tools |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 21 - Separation of Hydrocarbon Mixture |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 22 - Synthesis of Acetaldehyde from Ethanol |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 23 - BTX Separation through Distillation |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 24 - Synthesis of Methanol from Syngas |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 25 - Synthesis of Dimethyl Ether from Carbon Dioxide and Hydrogen |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 26 - Synthesis of Ammonia in Cryogenic Process |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 27 - Production of Cumene |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 28 - Design, Rating and Simulation of Heat Exchanger |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 29 - Absorption and Distillation - Part 1 |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 30 - Absorption and Distillation - Part 2 |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 31 - Hydrodealkylation of Toluene |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 32 - Isobutene Production Plant |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 33 - Nitric Oxide Production Plant |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 34 - Plant Economy and Utilities |
Link |
NOC:Aspen Plus® Simulation Software - A basic course for beginners |
Lecture 35 - Plant Dynamics and Control |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 1 - Introduction of Characterization Techniques - Part 1 |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 2 - Introduction to Characterization Techniques - Part 2 |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 3 - Infrared Spectroscopy: Fundamentals |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 4 - Infrared Spectroscopy: IR Bands and Applications |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 5 - Infrared Spectrophotometer Instrumentation |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 6 - Raman Spectroscopy |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 7 - NMR: Concepts and Fundamentals​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 8 - Chemical Shifts |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 9 - Factors Affecting Chemical Shift and 2D NMR​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 10 - Physisorption: Surface Area and Pore Analysis |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 11 - Physisorption Measurements |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 12 - Chemisorption |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 13 - Surface Tension and its Measurement - Part 1 |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 14 - Surface Tension and its Measurement - Part 2 |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 15 - Interfacial Tension and its Application |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 16 - Interfacial Tension and Influence of Surface Curvature​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 17 - Rheology: Fundamentals and Principles​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 18 - Complex Fluids and their Properties​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 19 - Rheology: Case Study on Hydrogel Synthesis |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 20 - Electron Spectroscopy for Surface Analysis​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 21 - Quantification in XRF and XPS Spectroscopy​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 22 - XPS Instrument and Application​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 23 - Introduction to Electrochemical Characterization Techniques​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 24 - Electrode Potential, Kinetics and Mass Transfer Resistance​ |
Link |
NOC:Physical and Electrochemical Characterizations in Chemical Engineering |
Lecture 25 - Voltammetry and Galvanostatic Charge-Discharge​ |
Link |
Fluid Mechanics |
Lecture 1 |
Link |
Fluid Mechanics |
Lecture 2 |
Link |
Fluid Mechanics |
Lecture 3 |
Link |
Fluid Mechanics |
Lecture 4 |
Link |
Fluid Mechanics |
Lecture 5 |
Link |
Fluid Mechanics |
Lecture 6 |
Link |
Fluid Mechanics |
Lecture 7 |
Link |
Fluid Mechanics |
Lecture 8 |
Link |
Fluid Mechanics |
Lecture 9 |
Link |
Fluid Mechanics |
Lecture 10 |
Link |
Fluid Mechanics |
Lecture 11 |
Link |
Fluid Mechanics |
Lecture 12 |
Link |
Fluid Mechanics |
Lecture 13 |
Link |
Fluid Mechanics |
Lecture 14 |
Link |
Fluid Mechanics |
Lecture 15 |
Link |
Fluid Mechanics |
Lecture 16 |
Link |
Fluid Mechanics |
Lecture 17 |
Link |
Fluid Mechanics |
Lecture 18 |
Link |
Fluid Mechanics |
Lecture 19 |
Link |
Fluid Mechanics |
Lecture 20 |
Link |
Fluid Mechanics |
Lecture 21 |
Link |
Fluid Mechanics |
Lecture 22 |
Link |
Fluid Mechanics |
Lecture 23 |
Link |
Fluid Mechanics |
Lecture 24 |
Link |
Fluid Mechanics |
Lecture 25 |
Link |
Fluid Mechanics |
Lecture 26 |
Link |
Fluid Mechanics |
Lecture 27 |
Link |
Fluid Mechanics |
Lecture 28 |
Link |
Fluid Mechanics |
Lecture 29 |
Link |
Fluid Mechanics |
Lecture 30 |
Link |
Fluid Mechanics |
Lecture 31 |
Link |
Fluid Mechanics |
Lecture 32 |
Link |
Fluid Mechanics |
Lecture 33 |
Link |
Fluid Mechanics |
Lecture 34 |
Link |
Fluid Mechanics |
Lecture 35 |
Link |
Fluid Mechanics |
Lecture 36 |
Link |
Fluid Mechanics |
Lecture 37 |
Link |
Fluid Mechanics |
Lecture 38 |
Link |
Fluid Mechanics |
Lecture 39 |
Link |
Fluid Mechanics |
Lecture 40 |
Link |
Mass Transfer II |
Lecture 1 |
Link |
Mass Transfer II |
Lecture 2 |
Link |
Mass Transfer II |
Lecture 3 |
Link |
Mass Transfer II |
Lecture 4 |
Link |
Mass Transfer II |
Lecture 5 |
Link |
Mass Transfer II |
Lecture 6 |
Link |
Mass Transfer II |
Lecture 7 |
Link |
Mass Transfer II |
Lecture 8 |
Link |
Mass Transfer II |
Lecture 9 |
Link |
Mass Transfer II |
Lecture 10 |
Link |
Mass Transfer II |
Lecture 11 |
Link |
Mass Transfer II |
Lecture 12 |
Link |
Mass Transfer II |
Lecture 13 |
Link |
Mass Transfer II |
Lecture 14 |
Link |
Mass Transfer II |
Lecture 15 |
Link |
Mass Transfer II |
Lecture 16 |
Link |
Mass Transfer II |
Lecture 17 |
Link |
Mass Transfer II |
Lecture 18 |
Link |
Mass Transfer II |
Lecture 19 |
Link |
Mass Transfer II |
Lecture 20 |
Link |
Mass Transfer II |
Lecture 21 |
Link |
Mass Transfer II |
Lecture 22 |
Link |
Mass Transfer II |
Lecture 23 |
Link |
Mass Transfer II |
Lecture 24 |
Link |
Mass Transfer II |
Lecture 25 |
Link |
Mass Transfer II |
Lecture 26 |
Link |
Mass Transfer II |
Lecture 27 |
Link |
Mass Transfer II |
Lecture 28 |
Link |
Mass Transfer II |
Lecture 29 |
Link |
Mass Transfer II |
Lecture 30 |
Link |
Mass Transfer II |
Lecture 31 |
Link |
Mass Transfer II |
Lecture 32 |
Link |
Mass Transfer II |
Lecture 33 |
Link |
Mass Transfer II |
Lecture 34 |
Link |
Mass Transfer II |
Lecture 35 |
Link |
Mass Transfer II |
Lecture 36 |
Link |
Mass Transfer II |
Lecture 37 |
Link |
Mass Transfer II |
Lecture 38 |
Link |
Mass Transfer II |
Lecture 39 |
Link |
Mass Transfer II |
Lecture 40 |
Link |
Plantwide Control of Chemical Processes |
Lecture 1 - Introduction to the course |
Link |
Plantwide Control of Chemical Processes |
Lecture 2 - Process Dynamics and Negative Feedback |
Link |
Plantwide Control of Chemical Processes |
Lecture 3 - PID control |
Link |
Plantwide Control of Chemical Processes |
Lecture 4 - Common Industrial Control Loops and advanced loops |
Link |
Plantwide Control of Chemical Processes |
Lecture 5 - Advanced loops (Continued...) and multivariable systems |
Link |
Plantwide Control of Chemical Processes |
Lecture 6 - Systematic Tuning Using Frequency Domain Analysis |
Link |
Plantwide Control of Chemical Processes |
Lecture 7 - Frequency Domain Analysis |
Link |
Plantwide Control of Chemical Processes |
Lecture 8 - Multivariable Systems |
Link |
Plantwide Control of Chemical Processes |
Lecture 9 - RGA and dynamic decoupling |
Link |
Plantwide Control of Chemical Processes |
Lecture 10 - Model based control |
Link |
Plantwide Control of Chemical Processes |
Lecture 11 - Dynamic Matrix Control |
Link |
Plantwide Control of Chemical Processes |
Lecture 12 - Control of Distillation Columns |
Link |
Plantwide Control of Chemical Processes |
Lecture 13 - Temperature inferential distillation control |
Link |
Plantwide Control of Chemical Processes |
Lecture 14 - Considerations in temperature inferential control |
Link |
Plantwide Control of Chemical Processes |
Lecture 15 - Control of Complex Column Configurations |
Link |
Plantwide Control of Chemical Processes |
Lecture 16 - Control of Heat Integrated Columns |
Link |
Plantwide Control of Chemical Processes |
Lecture 17 - Homogenous extractive distillation |
Link |
Plantwide Control of Chemical Processes |
Lecture 18 - More on complex columns and reactive distillation |
Link |
Plantwide Control of Chemical Processes |
Lecture 19 - Control of reactors |
Link |
Plantwide Control of Chemical Processes |
Lecture 20 - PFR controls (Continued..) & CSTRs |
Link |
Plantwide Control of Chemical Processes |
Lecture 21 - CSTR heat management |
Link |
Plantwide Control of Chemical Processes |
Lecture 22 - Heat Exchangers and Miscellaneous Systems |
Link |
Plantwide Control of Chemical Processes |
Lecture 23 - Degrees of freedom analysis |
Link |
Plantwide Control of Chemical Processes |
Lecture 24 - Degrees of freedom (Continued...) |
Link |
Plantwide Control of Chemical Processes |
Lecture 25 - Illustration of considerations in control structure synthesis |
Link |
Plantwide Control of Chemical Processes |
Lecture 26 - Two column recycle process |
Link |
Plantwide Control of Chemical Processes |
Lecture 27 - Throughput manipulator selection |
Link |
Plantwide Control of Chemical Processes |
Lecture 28 - Plantwide control structure design |
Link |
Plantwide Control of Chemical Processes |
Lecture 29 - Systematizing plantwide control design |
Link |
Plantwide Control of Chemical Processes |
Lecture 30 - The Luyben design procedure |
Link |
Plantwide Control of Chemical Processes |
Lecture 31 - Role of equipment capacity constraints |
Link |
Plantwide Control of Chemical Processes |
Lecture 32 - Recycle process case study |
Link |
Plantwide Control of Chemical Processes |
Lecture 33 - Recycle process case study (Continued...) |
Link |
Plantwide Control of Chemical Processes |
Lecture 34 - C4 isomerization process case study |
Link |
Plantwide Control of Chemical Processes |
Lecture 35 - C4 isomerization process case study (Continued...) |
Link |
Plantwide Control of Chemical Processes |
Lecture 36 - C4 isomerization process case study |
Link |
Plantwide Control of Chemical Processes |
Lecture 37 - Systematic economic plantwide control design procedure |
Link |
Plantwide Control of Chemical Processes |
Lecture 38 - Ethyl benzene process case study |
Link |
Plantwide Control of Chemical Processes |
Lecture 39 - C4 isomerization process revisited |
Link |
Plantwide Control of Chemical Processes |
Lecture 40 - Contrasting conventional and top-down approach |
Link |
Plantwide Control of Chemical Processes |
Lecture 41 - Cumene process plantwide control |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 1 - Review - 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 2 - Review - Temperature and Pressure |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 3 - Review - Energy Conservation |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 4 - Properties - Part 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 5 - Properties - Part 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 6 - Mass-energy analysis of open system |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 7 - Energy analysis of closed system |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 8 - The Second Law of Thermodynamics |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 9 - Entropy |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 10 - Thermodynamic Calculus - 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 11 - Thermodynamic Calculus - 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 12 - Thermodynamic Calculus - 3 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 13 - Thermodynamic Calculus - 4 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 14 - Legendre Transformation and Free-energy |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 15 - Criteria for phase equilibria |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 16 - Maxwell Relation |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 17 - Stability Criteria |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 18 - Thermodynamics of phase equilibrium |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 19 - Chemical potential and fugacity |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 20 - General discussion on fugacity |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 21 - Ideal Gas Mixture - Part 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 22 - Ideal Gas Mixture - Part 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 23 - Partial Molar Properties |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 24 - Partial Molar Properties from experimental data |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 25 - Thermodynamics properties from volumetric data - 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 26 - Thermodynamics properties from volumetric data - 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 27 - Fugacity of pure liquids and solids |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 28 - Thermodynamics properties from volumetric data: effect of V and T |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 29 - Approaches to phase equilibria calculation |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 30 - Traditional Approaches to phase equilibria calculations |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 31 - Algorithms for vapor-liquid equilibria |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 32 - Probability and Multiplicity |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 33 - Multiplicity and maximising the multiplicity |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 34 - Introduction to statistical mechanics |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 35 - Partition function for independent particles |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 36 - Intermolecular Forces |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 37 - Models of Molecular Pair Potentials |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 38 - Molecular Theory of Corresponding States |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 39 - Molecular Interactions in Dense Fluid Media |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 40 - Models for Electrolyte Systems |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 41 - Membrane Osmometry |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 42 - Fugacity of liquid mixture - 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 43 - Fugacity of liquid mixture - 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 44 - Models for fugacity of liquid mixtures - 1 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 45 - Models for fugacity of liquid mixtures - 2 |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 46 - Examples of Fugacity of liquids |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 47 - Stability of the Fluid Phases |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 48 - Theories of Solution - I |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 49 - Theories of Solution - II |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 50 - Polymer Solutions |
Link |
NOC:Thermodynamics Of Fluid Phase Equilibria |
Lecture 51 - Example Problems on Polymer Solutions |
Link |
NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 1 - Introduction |
Link |
NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 2 - Measurability and controllability of energy |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 3 - Postulates of thermodynamics - I |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 4 - Postulates of thermodynamics - II |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 5 - Definition of intensive variables and driving forces for temperature and pressure flow |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 6 - Driving force for the matter flow |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 7 - Basic properties, phase diagram, and thermodynamic table |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 8 - Work, and heat |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 9 - First law of thermodynamics for closed system: Ideal gas behavior |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 10 - First law of thermodynamics: Example 1 |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 11 - First law of thermodynamics for open system |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 12 - First law of thermodynamics: Example 2 |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 13 - The second law of the thermodynamics: Review |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 14 - Carnot cycle and thermodynamic temperature |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 15 - The concept of entropy |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 16 - Maximum work and entropy of ideal gas |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 17 - Power cycles and examples |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 18 - Mathematical properties of fundamental equations |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 19 - Generalized thermodynamic potential - I |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 20 - Generalized thermodynamic potential - II |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 21 - Multivariable Calculus |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 22 - Maxwell's relations and examples |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 23 - Jacobian method and its applications |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 24 - Equilibrium and stability - I |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 25 - Equilibrium and stability - II |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 26 - Stability criteria |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 27 - Intrinsic stability of thermodynamic system |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 28 - Phase transitions |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 29 - Clapeyron Equation and Vapour Pressure Correlations |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 30 - Equation of state |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 31 - Equation of state (Continued...) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 32 - Repulsive Interaction |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 33 - Fugacity |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 34 - Thermodynamics of mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 35 - Partial molar properties and examples |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 36 - Examples of partial molar properties for real processes |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 37 - Obtaining the partial molar properties from experimental data |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 38 - Partial molar properties of ideal gas mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 39 - Chemical potential of ideal gas mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 40 - Fugacity coefficient in terms of measurable properties |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 41 - Fugacity coefficient for mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 42 - Fugacity coefficient for ideal mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 43 - Activity coefficient for mixtures |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 44 - Gibbs - Duhem relations and its impacts on the activity |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 45 - Excess Gibbs free energy model - I |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 46 - Two suffix Margules equation |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 47 - Excess Gibbs free energy model - II |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 48 - Vapor Liquid Equilibria |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 49 - Vapor Liquid Equilibria (examples) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 50 - Vapor Liquid Equilibria (non-ideal mixtures - I) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 51 - Vapor Liquid Equilibria (non-ideal mixtures - II) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 52 - Azeotropes |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 53 - Azeotrope (binary mixture) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 54 - Liquid-Liquid equilibria - 1 |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 55 - liquid-liquid equilibria (Continued...) and solid-liquid equilibria |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 56 - Solid-liquid equilibria (Continued...) |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 57 - Solid-liquid equilibria examples and properties |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 58 - Examples of boiling point elevation |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 59 - Solubility of gases in the liquid |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 60 - Chemical reaction equilibria - I |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 61 - Chemical reaction equilibria - II |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 62 - Chemical reaction equilibria - III |
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NOC:Chemical Engineering Thermodynamics (2019) |
Lecture 63 - Chemical reaction equilibria - IV |
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Biochemical Engineering |
Lecture 1 - Fundamentals of Biology & Biotechnology |
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Biochemical Engineering |
Lecture 2 - Glimpses of Microbial World - Bacteria |
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Biochemical Engineering |
Lecture 3 - Virus and Cell Organelles |
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Biochemical Engineering |
Lecture 4 - Carbohydrate |
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Biochemical Engineering |
Lecture 5 - Nucleic Acid |
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Biochemical Engineering |
Lecture 6 - Lipids |
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Biochemical Engineering |
Lecture 7 - Proteins |
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Biochemical Engineering |
Lecture 8 - Biochemistry & Thermodynamics of Enzymes |
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Biochemical Engineering |
Lecture 9 - Enzyme Kinetics : Michealis-Menten Kinetics |
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Biochemical Engineering |
Lecture 10 - Regulation of Enzyme Activity : Inhibition |
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Biochemical Engineering |
Lecture 11 - Regulation of Enzyme Activity : Inhibition (Continued...) |
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Biochemical Engineering |
Lecture 12 - Effects of Substrate and Inhibition, pH and Temperature on Enzyme Activity |
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Biochemical Engineering |
Lecture 13 - Immobilized Enzymes |
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Biochemical Engineering |
Lecture 14 - Immobilized Enzymes (Continued...) |
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Biochemical Engineering |
Lecture 15 - Interphase Mass Transfer and Reaction in Immobilized Enzymes |
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Biochemical Engineering |
Lecture 16 - Interphase Mass Transfer and Reaction in Immobilized Enzymes (Continued...) |
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Biochemical Engineering |
Lecture 17 - Effectiveness Factor in Immobilized Enzymes |
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Biochemical Engineering |
Lecture 18 - Bioenergetics and Glycolysis |
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Biochemical Engineering |
Lecture 19 - TCA Cycle |
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Biochemical Engineering |
Lecture 20 - Electron Transport Chain & Oxidative Phosphorylation |
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Biochemical Engineering |
Lecture 21 - Pentose Phosphate Pathways Glycogenesis & Glycogenolysis |
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Biochemical Engineering |
Lecture 22 - Urea Cycle, Gluconeogenesis and Glyoxalate Cycle |
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Biochemical Engineering |
Lecture 23 - Microbial Growth : Phases and Models |
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Biochemical Engineering |
Lecture 24 - Effect of Mass Transfer on Microbial & Fungal Growth |
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Biochemical Engineering |
Lecture 25 - Effect of Multiple Substrates and Inhibition on Microbial Growth |
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Biochemical Engineering |
Lecture 26 - Design of Bioreactors |
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Biochemical Engineering |
Lecture 27 - Design of Chemostats |
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Biochemical Engineering |
Lecture 28 - Stability of Bioreactors |
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Biochemical Engineering |
Lecture 29 - Stability of Bioreactors (Continued...) |
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Biochemical Engineering |
Lecture 30 - Introduction to Receptor - Ligand Binding |
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Biochemical Engineering |
Lecture 31 - Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics |
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Biochemical Engineering |
Lecture 32 - Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics (Continued...) |
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Biochemical Engineering |
Lecture 33 - Receptors-Mediated Endocytosis |
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Biochemical Engineering |
Lecture 34 - Kinetics of Receptor-Mediated Endocytosis |
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Biochemical Engineering |
Lecture 35 - General Model for Receptor-Mediated Endocytosis |
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Biochemical Engineering |
Lecture 36 - Multiple Interacting Microbial Population: Prey-Predator Models |
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Biochemical Engineering |
Lecture 37 - Manufacture of Biochemicals |
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Biochemical Engineering |
Lecture 38 - Manufacture of Biochemicals (Continued...) & Strategies for Biomolecules Separation |
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Biochemical Engineering |
Lecture 39 - Strategies for Biomolecules Separation (Continued...) |
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Biochemical Engineering |
Lecture 40 - Strategies for Biomolecules Separation (Continued...) |
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Microscale Transport Processes |
Lecture 1 - Introduction |
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Microscale Transport Processes |
Lecture 2 - Introduction (Continued...) |
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Microscale Transport Processes |
Lecture 3 - Lab on Chip |
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Microscale Transport Processes |
Lecture 4 - Lab on Chip (Continued...) |
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Microscale Transport Processes |
Lecture 5 - Microscale manufacturing practices |
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Microscale Transport Processes |
Lecture 6 - Photolithography |
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Microscale Transport Processes |
Lecture 7 - Photolithography (Continued...) |
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Microscale Transport Processes |
Lecture 8 - Deposition |
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Microscale Transport Processes |
Lecture 9 - Plastic microfluidic devices |
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Microscale Transport Processes |
Lecture 10 - Mixing |
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Microscale Transport Processes |
Lecture 11 - Micro Heat Pipes |
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Microscale Transport Processes |
Lecture 12 - Mixing (Continued...) |
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Microscale Transport Processes |
Lecture 13 - Mixing (Continued...) |
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Microscale Transport Processes |
Lecture 14 - Micro Heat Pipes (Continued...) |
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Microscale Transport Processes |
Lecture 15 - Mixing (Continued...) |
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Microscale Transport Processes |
Lecture 16 - Dispersion |
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Microscale Transport Processes |
Lecture 17 - Dispersion (Continued...) |
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Microscale Transport Processes |
Lecture 18 - Dispersion (Continued...) |
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Microscale Transport Processes |
Lecture 19 - Electrowetting |
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Microscale Transport Processes |
Lecture 20 - Electro osmosis |
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Microscale Transport Processes |
Lecture 21 - Electrowetting (Continued...) |
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Microscale Transport Processes |
Lecture 22 - Electro osmosis (Continued...) |
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Microscale Transport Processes |
Lecture 23 - Dielectrophoresis |
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Microscale Transport Processes |
Lecture 24 - Dielectrophoresis (Continued...) |
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Microscale Transport Processes |
Lecture 25 - Dielectrophoresis (Continued...) |
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Microscale Transport Processes |
Lecture 26 - Scaling dimension and issues |
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Microscale Transport Processes |
Lecture 27 - Slip flow |
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Microscale Transport Processes |
Lecture 28 - Microstructured reactor |
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Microscale Transport Processes |
Lecture 29 - Immiscible flow in microchannel |
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Microscale Transport Processes |
Lecture 30 - Immiscible flow in microchannel (Continued...) |
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Microscale Transport Processes |
Lecture 31 - Immiscible flow in microchannel (Continued...) |
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Microscale Transport Processes |
Lecture 32 - Scaling dimension and issues (Continued...) |
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Microscale Transport Processes |
Lecture 33 - Immiscible flow in microchannel (Continued...) |
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Microscale Transport Processes |
Lecture 34 - Plastic device making |
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Microscale Transport Processes |
Lecture 35 - Transport processes and their descriptions |
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Microscale Transport Processes |
Lecture 36 - Convective fluid dynamics in microchannels |
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Microscale Transport Processes |
Lecture 37 - Microfluidic networks |
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Microscale Transport Processes |
Lecture 38 - Electrohydrodynamic atomization |
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Microscale Transport Processes |
Lecture 39 - Electrohydrodynamic atomization (Continued...) |
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Microscale Transport Processes |
Lecture 40 - Interfacial phenomena in thin liquid films |
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Multiphase Flow |
Lecture 1 - Introduction |
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Multiphase Flow |
Lecture 2 - Estimation of Flow Patterns |
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Multiphase Flow |
Lecture 3 - Estimation of Flow Patterns (Continued...) |
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Multiphase Flow |
Lecture 4 - Flow Pattern Maps Fascinating Taylor Bubbles |
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Multiphase Flow |
Lecture 5 - Definitions and Common Terminologies |
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Multiphase Flow |
Lecture 6 - Definitions and Common Terminologies (Continued...) |
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Multiphase Flow |
Lecture 7 - Simple Analytical Models |
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Multiphase Flow |
Lecture 8 - The Homogeneous Flow Theory |
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Multiphase Flow |
Lecture 9 - The Homogeneous Flow Theory (Continued...) |
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Multiphase Flow |
Lecture 10 - Compressible Flow A Recapitulation |
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Multiphase Flow |
Lecture 11 - Compressible Flow A Recapitulation (Continued...) |
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Multiphase Flow |
Lecture 12 - Choked Flow Condition for Homogeneous Flow |
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Multiphase Flow |
Lecture 13 - Drift Flux Model |
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Multiphase Flow |
Lecture 14 - Drift Flux Model (Continued...) |
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Multiphase Flow |
Lecture 15 - Drift Flux Model (Continued...) |
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Multiphase Flow |
Lecture 16 - Drift Flux Model (Continued...) |
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Multiphase Flow |
Lecture 17 - Separated Flow Model |
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Multiphase Flow |
Lecture 18 - Separated Flow Model (Continued...) |
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Multiphase Flow |
Lecture 19 - Separated Flow Model (Continued...) |
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Multiphase Flow |
Lecture 20 - Separated Flow Model - Condition of Choking |
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Multiphase Flow |
Lecture 21 - Separated Flow Model - Condition of Choking (Continued...) |
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Multiphase Flow |
Lecture 22 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction |
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Multiphase Flow |
Lecture 23 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...) |
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Multiphase Flow |
Lecture 24 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...) |
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Multiphase Flow |
Lecture 25 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...) |
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Multiphase Flow |
Lecture 26 - Analysis of Specific Flow Regimes |
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Multiphase Flow |
Lecture 27 - Analysis of Specific Flow Regimes (Continued...) |
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Multiphase Flow |
Lecture 28 - Analysis of Specific Flow Regimes - Slug Flow (Continued...) |
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Multiphase Flow |
Lecture 29 - Two Phase Flow with Phase Change - An Introduction to Boiling Heat Transfer |
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Multiphase Flow |
Lecture 30 - Bubble Growth |
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Multiphase Flow |
Lecture 31 - Different Types of Nucleation |
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Multiphase Flow |
Lecture 32 - Ibullition from Hot Surfaces |
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Multiphase Flow |
Lecture 33 - Cycle of Bubble Growth and Departure |
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Multiphase Flow |
Lecture 34 - Heat Transfer in Different Regimes of Boiling |
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Multiphase Flow |
Lecture 35 - Heat Transfer in Different Regimes of Boiling (Continued...) |
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Multiphase Flow |
Lecture 36 - Critical Heat Flux, Film Boiling |
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Multiphase Flow |
Lecture 37 - Measurement Techniques for Two Phase flow Parameters |
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Multiphase Flow |
Lecture 38 - Measurement Techniques for Two Phase flow Parameters - Void Fraction Measurement |
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Multiphase Flow |
Lecture 39 - Measurement Techniques for Two Phase flow Parameters - Void Fraction Measurement (Continued...) |
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Multiphase Flow |
Lecture 40 - Measurement Techniques for Two Phase flow Parameters - Estimation of Flow Patterns |
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Novel Separation Processes |
Lecture 1 - Fundamentals of Separation Processes |
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Novel Separation Processes |
Lecture 2 - Identification of Novel Separation Processes |
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Novel Separation Processes |
Lecture 3 - Membrane Separation Processes |
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Novel Separation Processes |
Lecture 4 - Membrane Separation Processes (Continued...1) |
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Novel Separation Processes |
Lecture 5 - Membrane Separation Processes (Continued...2) |
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Novel Separation Processes |
Lecture 6 - Membrane Separation Processes (Continued...3) |
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Novel Separation Processes |
Lecture 7 - Membrane Separation Processes (Continued...4) |
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Novel Separation Processes |
Lecture 8 - Membrane Separation Processes (Continued...5) |
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Novel Separation Processes |
Lecture 9 - Membrane Separation Processes (Continued...6) |
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Novel Separation Processes |
Lecture 10 - Membrane Separation Processes (Continued...7) |
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Novel Separation Processes |
Lecture 11 - Membrane Separation Processes (Continued...8) |
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Novel Separation Processes |
Lecture 12 - Membrane Separation Processes (Continued...9) |
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Novel Separation Processes |
Lecture 13 - Membrane Separation Processes (Continued...10) |
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Novel Separation Processes |
Lecture 14 - Membrane Separation Processes (Continued...11) |
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Novel Separation Processes |
Lecture 15 - Membrane Separation Processes (Continued...12) |
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Novel Separation Processes |
Lecture 16 - Membrane Separation Processes (Continued...13) |
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Novel Separation Processes |
Lecture 17 - Membrane Separation Processes (Continued...14) |
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Novel Separation Processes |
Lecture 18 - Membrane Separation Processes (Continued...15) |
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Novel Separation Processes |
Lecture 19 - Membrane Separation Processes (Continued...16) |
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Novel Separation Processes |
Lecture 20 - Membrane Separation Processes (Continued...17) |
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Novel Separation Processes |
Lecture 21 - Membrane Separation Processes (Continued...18) |
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Novel Separation Processes |
Lecture 22 - External Field Induced Membrane Separation Processes |
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Novel Separation Processes |
Lecture 23 - External Field Induced Membrane Separation Processes (Continued...1) |
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Novel Separation Processes |
Lecture 24 - External Field Induced Membrane Separation Processes (Continued...2) |
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Novel Separation Processes |
Lecture 25 - External Field Induced Membrane Separation Processes (Continued...3) |
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Novel Separation Processes |
Lecture 26 - External Field Induced Membrane Separation Processes (Continued...4) |
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Novel Separation Processes |
Lecture 27 - Gas Separation |
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Novel Separation Processes |
Lecture 28 - Gas Separation (Continued...) |
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Novel Separation Processes |
Lecture 29 - Surfactant Based Separation Processes |
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Novel Separation Processes |
Lecture 30 - Surfactant Based Separation Processes (Continued...) |
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Novel Separation Processes |
Lecture 31 - Micellar Enhanced Ultrafiltration |
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Novel Separation Processes |
Lecture 32 - Micellar Enhanced Ultrafiltration (Continued...) |
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Novel Separation Processes |
Lecture 33 - Liquid Membranes |
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Novel Separation Processes |
Lecture 34 - Liquid Membranes (Continued...) |
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Novel Separation Processes |
Lecture 35 - Centrifugal Separation Processes |
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Novel Separation Processes |
Lecture 36 - Chromatographic Separation Processes |
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Novel Separation Processes |
Lecture 37 - Chromatographic Separation Processes (Continued...) |
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Novel Separation Processes |
Lecture 38 - Ion Exchange Processes |
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Novel Separation Processes |
Lecture 39 - Electrophoretic Separation Methods |
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Novel Separation Processes |
Lecture 40 - Electrophoretic Separation Methods (Continued...) |
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Novel Separation Processes |
Lecture 41 - Supercritical Fluid Extraction |
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Process Control and Instrumentation |
Lecture 1 - Introduction to Process Control |
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Process Control and Instrumentation |
Lecture 2 - Introduction to Process Control (Continued...) |
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Process Control and Instrumentation |
Lecture 3 - Mathematical Modeling (Continued...1) |
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Process Control and Instrumentation |
Lecture 4 - Mathematical Modeling (Continued...2) |
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Process Control and Instrumentation |
Lecture 5 - Mathematical Modeling (Continued...3) |
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Process Control and Instrumentation |
Lecture 6 - Dynamic Behavior of Chemical Processes |
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Process Control and Instrumentation |
Lecture 7 - Dynamic Behavior of Chemical Processes (Continued...1) |
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Process Control and Instrumentation |
Lecture 8 - Dynamic Behavior of Chemical Processes (Continued...2) |
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Process Control and Instrumentation |
Lecture 9 - Dynamic Behavior of Chemical Processes (Continued...3) |
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Process Control and Instrumentation |
Lecture 10 - Dynamic Behavior of Chemical Processes (Continued...4) |
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Process Control and Instrumentation |
Lecture 11 - Dynamic Behavior of Chemical Processes (Continued...5) |
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Process Control and Instrumentation |
Lecture 12 - Dynamic Behavior of Chemical Processes (Continued...6) |
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Process Control and Instrumentation |
Lecture 13 - Dynamic Behavior of Chemical Processes (Continued...7) |
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Process Control and Instrumentation |
Lecture 14 - Dynamic Behavior of Chemical Processes (Continued...8) |
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Process Control and Instrumentation |
Lecture 15 - Feedback Control Schemes |
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Process Control and Instrumentation |
Lecture 16 - Feedback Control Schemes (Continued...1) |
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Process Control and Instrumentation |
Lecture 17 - Feedback Control Schemes (Continued...2) |
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Process Control and Instrumentation |
Lecture 18 - Feedback Control Schemes (Continued...3) |
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Process Control and Instrumentation |
Lecture 19 - Feedback Control Schemes (Continued...4) |
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Process Control and Instrumentation |
Lecture 20 - Feedback Control Schemes (Continued...5) |
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Process Control and Instrumentation |
Lecture 21 - Feedback Control Schemes (Continued...6) |
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Process Control and Instrumentation |
Lecture 22 - Feedback Control Schemes (Continued...7) |
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Process Control and Instrumentation |
Lecture 23 - Feedback Control Schemes (Continued...8) |
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Process Control and Instrumentation |
Lecture 24 - Feedback Control Schemes (Continued...9) |
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Process Control and Instrumentation |
Lecture 25 - Feedback Control Schemes (Continued...10) |
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Process Control and Instrumentation |
Lecture 26 - Feedback Control Schemes (Continued...11) |
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Process Control and Instrumentation |
Lecture 27 - Feedback Control Schemes (Continued...12) |
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Process Control and Instrumentation |
Lecture 28 - Feedback Control Schemes (Continued...13) |
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Process Control and Instrumentation |
Lecture 29 - Feedback Control Schemes (Continued...14) |
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Process Control and Instrumentation |
Lecture 30 - Advanced Control Schemes |
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Process Control and Instrumentation |
Lecture 31 - Advanced Control Schemes (Continued...1) |
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Process Control and Instrumentation |
Lecture 32 - Advanced Control Schemes (Continued...2) |
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Process Control and Instrumentation |
Lecture 33 - Advanced Control Schemes (Continued...3) |
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Process Control and Instrumentation |
Lecture 34 - Advanced Control Schemes (Continued...4) |
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Process Control and Instrumentation |
Lecture 35 - Instrumentation: General Principles of Measurement Systems |
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Process Control and Instrumentation |
Lecture 36 - Instrumentation: General Principles of Measurement Systems (Continued...1) |
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Process Control and Instrumentation |
Lecture 37 - Instrumentation: General Principles of Measurement Systems (Continued...2) |
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Process Control and Instrumentation |
Lecture 38 - Instrumentation: General Principles of Measurement Systems (Continued...3) |
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Process Control and Instrumentation |
Lecture 39 - Instrumentation: General Principles of Measurement Systems (Continued...4) |
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Process Control and Instrumentation |
Lecture 40 - Instrumentation: General Principles of Measurement Systems (Continued...5) |
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Process Control and Instrumentation |
Lecture 41 - Transducer Elements |
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Process Control and Instrumentation |
Lecture 42 - Pressure Measurement |
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Process Control and Instrumentation |
Lecture 43 - Pressure Measurement (Continued...1) |
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Process Control and Instrumentation |
Lecture 44 - Pressure Measurement (Continued...2) |
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Instability and Patterning of Thin Polymer Films |
Lecture 1 - Introduction |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 2 - Introduction (Continued...) |
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Instability and Patterning of Thin Polymer Films |
Lecture 3 - Some Fundamental Surface Related Concepts - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 4 - Surface Tension (in terms of molecular interactions) |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 5 - Effect Surface Tension : Laplace Pressure |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 6 - Young Laplace Equation |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 7 - Rayleish Instability |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 8 - Meso Scale Fabrication Approaches |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 9 - Photo Lithography - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 10 - Photo Lithography - II |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 11 - Photo Lithography - III |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 12 - Photo Lithography - IV |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 13 - Photo Lithography - V |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 14 - Nano Imprint Lithography |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 15 - Nano Imprint Lithography (Continued...) |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 16 - Soft Lithography - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 17 - Soft Lithography - II |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 18 - Soft Lithography - III |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 19 - Soft Lithography - IV |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 20 - Soft Lithography - V |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 21 - Soft Lithography - VI |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 22 - Atomic Force Microscope - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 23 - Atomic Force Microscope - II |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 24 - Atomic Force Microscope - III |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 25 - Atomic Force Microscope - IV |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 26 - Atomic Force Microscope - V |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 27 - Intermolecular Forces between Particles and Surfaces - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 28 - Intermolecular Forces between Particles and Surfaces - II |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 29 - Intermolecular Forces between Particles and Surfaces - III |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 30 - Intermolecular Forces between Particles and Surfaces - IV |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 31 - Spontaneous instability and dwetting of thin polymer film - I |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 32 - Spontaneous instability and dwetting of thin polymer film - II |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 33 - Spontaneous instability and dwetting of thin polymer film - III |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 34 - Spontaneous instability and dwetting of thin polymer film - IV |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 35 - Spontaneous instability and dwetting of thin polymer film - V |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 36 - Spontaneous instability and dwetting of thin polymer film - VI |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 37 - Spontaneous instability and dwetting of thin polymer film - VII |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 38 - Template Guided Dewetting |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 39 - Elastic Contact Instability and Lithography |
Link |
Instability and Patterning of Thin Polymer Films |
Lecture 40 - Gradient Surfaces |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 1 - Introduction to vector space |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 2 - Introduction to vector space (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 3 - Onto, into, one to one function |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 4 - Vectors |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 5 - Vectors (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 6 - Contraction Mapping |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 7 - Contraction Mapping (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 8 - Matrix, Determinant |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 9 - Eigenvalue Problem in Discrete Domain |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 10 - Eigenvalue Problem in Discrete Domain (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 11 - Eigenvalue Problem in Discrete Domain (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 12 - Eigenvalue Problem in Discrete Domain (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 13 - Stability Analysis |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 14 - Stability Analysis (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 15 - Stability Analysis (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 16 - More Examples |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 17 - Partial Differential Equations |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 18 - Partial Differential Equations (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 19 - Eigenvalue Problem in Continuous Domain |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 20 - Special ODEs |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 21 - Adjoint Operator |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 22 - Theorems of Eigenvalues and Eigenfunction |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 23 - Solution PDE : Separation of Variables Method |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 24 - Solution of Parabolic PDE : Separation of variables method |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 25 - Solution of Parabolic PDE : Separation of Variables Method (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 26 - Solution of Higher Dimensional PDEs |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 27 - Solution of Higher Dimensional PDEs (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 28 - Four Dimensional Parabolic PDE |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 29 - Solution of Elliptic and Hyperbolic PDE |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 30 - Solution of Elliptic and Hyperbolic PDE (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 31 - PDE in Cylindrical and Spherical Coordinate |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 32 - Solution of non-homogeneous PDE |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 33 - Solution of non-homogeneous PDE (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 34 - Solution of non-homogeneous Parabolic PDE |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 35 - Solution of non-homogeneous Elliptic PDE |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 36 - Solution of non-homogeneous Elliptic PDE (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 37 - Similarity Solution |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 38 - Similarity Solution (Continued...) |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 39 - Integral Method |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 40 - Laplace Transform |
Link |
Advanced Mathematical Techniques in Chemical Engineering |
Lecture 41 - Fourier Transform |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 1 - Fundamentals of Separation Processes and Introduction of Membrane System |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 2 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 3 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 4 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 5 - Modeling of Reverse Osmosis |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 6 - Concentration Polarization |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 7 - Osmotic Pressure Controlling Filtration |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 8 - Osmotic Pressure Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 9 - Osmotic Pressure Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 10 - Osmotic Pressure Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 11 - Osmotic Pressure Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 12 - Osmotic Pressure Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 13 - Modeling of Gel Layer Controlling Filtration |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 14 - Modeling of Gel Layer Controlling Filtration (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 15 - Modeling of Gel Layer Controlling Filtration (Continued...) and Resistance in Series Models |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 16 - Design of Membrane Module |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 17 - Design of Membrane Module (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 18 - Design of Membrane Module (Continued...) |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 19 - Modeling of Dialysis |
Link |
NOC:Introduction to Process Modeling in Membrane Separation Process |
Lecture 20 - Modeling of Dialysis (Continued...) |
Link |
NOC:Soft Nano Technology |
Lecture 1 - Introduction - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 2 - Introduction - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 3 - Introduction - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 4 - Fundamental Concepts Related to Surface Tension - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 5 - Fundamental Concepts Related to Surface Tension - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 6 - Fundamental Concepts Related to Surface Tension - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 7 - Fundamental Concepts Related to Surface Tension - 4 |
Link |
NOC:Soft Nano Technology |
Lecture 8 - Components of Surface Tension - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 9 - Components of Surface Tension - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 10 - Sell Assembly of Surfactant Molecules |
Link |
NOC:Soft Nano Technology |
Lecture 11 - Laplace Pressure |
Link |
NOC:Soft Nano Technology |
Lecture 12 - Photo Lithography - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 13 - Photo Lithography - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 14 - Photo Lithography - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 15 - Photo Lithography - 4 |
Link |
NOC:Soft Nano Technology |
Lecture 16 - Photo Lithography - 5 |
Link |
NOC:Soft Nano Technology |
Lecture 17 - Photo Lithography - 6 |
Link |
NOC:Soft Nano Technology |
Lecture 18 - Soft Lithography - I |
Link |
NOC:Soft Nano Technology |
Lecture 19 - Soft Lithography - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 20 - Soft Lithography - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 21 - Soft Lithography - 4 |
Link |
NOC:Soft Nano Technology |
Lecture 22 - Soft Lithography - 5 |
Link |
NOC:Soft Nano Technology |
Lecture 23 - Soft Lithography - 6 |
Link |
NOC:Soft Nano Technology |
Lecture 24 - Atomic Force Microscope - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 25 - Atomic Force Microscope - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 26 - Atomic Force Microscope - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 27 - Atomic Force Microscope - 4 |
Link |
NOC:Soft Nano Technology |
Lecture 28 - Atomic Force Microscope - 5 |
Link |
NOC:Soft Nano Technology |
Lecture 29 - Atomic Force Microscope - 6 |
Link |
NOC:Soft Nano Technology |
Lecture 30 - Dewetting - 1 |
Link |
NOC:Soft Nano Technology |
Lecture 31 - Dewetting - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 32 - VdW Interaction Between Two Surfaces |
Link |
NOC:Soft Nano Technology |
Lecture 33 - Interaction Between Two Surfaces - 2 |
Link |
NOC:Soft Nano Technology |
Lecture 34 - Interaction Between Two Surfaces - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 35 - Dewetting - 3 |
Link |
NOC:Soft Nano Technology |
Lecture 36 - Pattern Directed Dewetting - I |
Link |
NOC:Soft Nano Technology |
Lecture 37 - Pattern Directed Dewetting - II |
Link |
NOC:Soft Nano Technology |
Lecture 38 - Spin Dewetting |
Link |
NOC:Soft Nano Technology |
Lecture 39 - Elastic Contact Instability - I |
Link |
NOC:Soft Nano Technology |
Lecture 40 - Elastic Contact Instability - II |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 1 - Brief Introduction to Multiphase Flow |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 2 - Brief Introduction to Multiphase Flow (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 3 - Two Phase Flow through Micro Channels |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 4 - Two Phase Flow through Micro Channels (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 5 - Criteria for Confinement for in Case of Two Phase Flow |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 6 - Pertinent Dimensionless Numbers in Two Phase |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 7 - Flow Pattern Maps for Milli and Micro Systems |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 8 - Pattern Transition from Energy Minimisation Principle |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 9 - Experimental Identification of Flow Regimes |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 10 - Experimental Identification of Flow Regimes (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 11 - Flow Regimes and Void Fraction Estimation |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 12 - Influence of Operating Parameter on Flow Patterns |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 13 - Influence of Operating Parameter on Flow Patterns (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 14 - Influence of Operating Parameter on Flow Patterns (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 15 - Influence of Operating Parameter on Flow Patterns (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 16 - Void Fraction Characteristic Mini and Micro Channel |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 17 - Void Fraction and Pressure Drop in Reduced Dimensions - Experimental results |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 18 - Void Fraction and Pressure Drop in Reduced Dimensions - Experimental results (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 19 - Theoretical Analysis of Two Phase Flow in Reduced Dimensions |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 20 - Theoretical Analysis of Two Phase Flow in Reduced Dimensions (Continued...) |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 21 - Flow Pattern based Analysis in Micro Systems - Drift Flux Model |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 22 - Flow Pattern based Modelling - Slug Flow Model |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 23 - Flow Boiling in Microchannels |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 24 - Tutorial - I |
Link |
NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel |
Lecture 25 - Tutorial - II |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 1 - Introduction |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 2 - Introduction (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 3 - First Law of Thermodynamics |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 4 - Second Law of Thermodynamics |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 5 - Second Law of Thermodynamics (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 6 - Entropy Change during Spontaneous Processes |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 7 - Criteria of Spontaneity |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 8 - Criteria of Spontaneity (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 9 - Thermodynamic Network |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 10 - Thermodynamic Network (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 11 - Tutorial 1 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 12 - Gibbs free energy as a function of temperature and pressure |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 13 - P-v-T behaviour of gases |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 14 - P-v-T behaviour (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 15 - P-v-T behaviour (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 16 - P-v-T behaviour (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 17 - Tutorial 2 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 18 - Property estimation from P-v-T behaviour |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 19 - Property estimation (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 20 - Concept of chemical potential |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 21 - Chemical potential (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 22 - Homogeneous open systems |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 23 - Homogeneous open systems (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 24 - Heterogeneous Closed Systems |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 25 - Tutorial 3 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 26 - Concept of fugacity |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 27 - Fugacity (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 28 - Estimation of fugacity coefficients |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 29 - Fugacity of condensed phase |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 30 - Mixtures |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 31 - Mixtures (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 32 - Tutorial 4 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 33 - Partial molar properties |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 34 - Partial molar properties (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 35 - Partial molar fugacity |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 36 - Ideal solutions |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 37 - Ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 38 - Ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 39 - Ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 40 - Non-ideal solutions |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 41 - Non-ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 42 - Non-ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 43 - Non-ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 44 - Non-ideal solutions (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 45 - Deviations from ideal dilute solutions |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 46 - Tutorial 5 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 47 - Tutorial 6 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 48 - Thermodynamics Consistency Test of VLE Data |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 49 - Retrograde Condensation |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 50 - Partial and Complete Immiscibility of Liquid Mixtures |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 51 - Partial and Complete Immiscibility of Liquid Mixtures (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 52 - Phase Equilibrium for Mass Transfer Processes |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 53 - Control Mass Analysis of Transient process |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 54 - Control Volume Analysis |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 55 - Throttling and problem |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 56 - Tutorial 7 |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 57 - First Law for reacting systems |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 58 - Estimation of standard heat of reaction |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 59 - Effect of operating variables on heat of reaction |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 60 - Chemical Reaction Equilibrium |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 61 - Equilibrium constant and its estimation |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 62 - Relation of Equilibrium constant to composition |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 63 - Effect of operating conditions on equilibrium conversion |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 64 - Relation of Equilibrium constant to composition (Continued...) |
Link |
NOC:Phase Equilibrium Thermodynamics |
Lecture 65 - Miscellaneous concepts on Reaction Equilibrium |
Link |
NOC:Transport Phenomena |
Lecture 1 - Introduction : Newton's Law of Viscosity |
Link |
NOC:Transport Phenomena |
Lecture 2 - Fourier and Fick's Laws |
Link |
NOC:Transport Phenomena |
Lecture 3 - Shell Momentum Balance |
Link |
NOC:Transport Phenomena |
Lecture 4 - Example of Shell Momentum Balance |
Link |
NOC:Transport Phenomena |
Lecture 5 - Example of Shell Momentum Balance (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 6 - Example of Shell Momentum Balance (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 7 - Example of Shell Momentum Balance (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 8 - Example of Shell Momentum Balance (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 9 - Equations of Change for Isothermal Systems |
Link |
NOC:Transport Phenomena |
Lecture 10 - Equations of Change for Isothermal Systems (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 11 - Equations of Change for Isothermal Systems (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 12 - Equations of Change for Isothermal Systems (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 13 - Equations of Change for Isothermal Systems (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 14 - Equations of Change for Isothermal Systems (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 15 - Unsteady Flow |
Link |
NOC:Transport Phenomena |
Lecture 16 - Boundary Layers |
Link |
NOC:Transport Phenomena |
Lecture 17 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 18 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 19 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 20 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 21 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 22 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 23 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 24 - Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 25 - Turbulent Boundary Layers |
Link |
NOC:Transport Phenomena |
Lecture 26 - Turbulent Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 27 - Turbulent Boundary Layers (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 28 - Drag |
Link |
NOC:Transport Phenomena |
Lecture 29 - Drag (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 30 - Heat Transfer Basics |
Link |
NOC:Transport Phenomena |
Lecture 31 - Heat Transfer Basics (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 32 - 1-D Heat Conduction - Temperature Distributions |
Link |
NOC:Transport Phenomena |
Lecture 33 - 1-D Heat Conduction - Shell Heat Balance |
Link |
NOC:Transport Phenomena |
Lecture 34 - Shell Heat Balance |
Link |
NOC:Transport Phenomena |
Lecture 35 - Viscous Dissipation |
Link |
NOC:Transport Phenomena |
Lecture 36 - Transient Conduction |
Link |
NOC:Transport Phenomena |
Lecture 37 - Transient Conduction (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 38 - Forced Convection |
Link |
NOC:Transport Phenomena |
Lecture 39 - Energy Equation |
Link |
NOC:Transport Phenomena |
Lecture 40 - Energy Equation (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 41 - Free Convection |
Link |
NOC:Transport Phenomena |
Lecture 42 - Thermal Boundary Layer |
Link |
NOC:Transport Phenomena |
Lecture 43 - Mass Transfer |
Link |
NOC:Transport Phenomena |
Lecture 44 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 45 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 46 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 47 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 48 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 49 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 50 - Mass Transfer (Continued...) |
Link |
NOC:Transport Phenomena |
Lecture 51 - Convection Transfer Equations |
Link |
NOC:Transport Phenomena |
Lecture 52 - Boundary Layer Similarity |
Link |
NOC:Transport Phenomena |
Lecture 53 - Boundary Layer - Analogy |
Link |
NOC:Transport Phenomena |
Lecture 54 - Analogy - Tutorial I |
Link |
NOC:Transport Phenomena |
Lecture 55 - Analogy - Tutorial II |
Link |
NOC:Transport Phenomena |
Lecture 56 - Analogy - Tutorial III |
Link |
NOC:Transport Phenomena |
Lecture 57 - Analogy - Tutorial IV and V |
Link |
NOC:Transport Phenomena |
Lecture 58 - Tutorial on Displacement Thickness |
Link |
NOC:Transport Phenomena |
Lecture 59 - Tutorial on Momentum Integral Equation |
Link |
NOC:Transport Phenomena |
Lecture 60 - Summary of the Course |
Link |
NOC:Chemical Process Instrumentation |
Lecture 1 - General Principles and Representation of Instruments |
Link |
NOC:Chemical Process Instrumentation |
Lecture 2 - General Principles and Representation of Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 3 - General Principles and Representation of Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 4 - General Principles and Representation of Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 5 - General Principles and Representation of Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 6 - Performance Characteristics of Instruments and Data Analysis - I |
Link |
NOC:Chemical Process Instrumentation |
Lecture 7 - Performance Characteristics of Instruments and Data Analysis - I (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 8 - Performance Characteristics of Instruments and Data Analysis - I (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 9 - Performance Characteristics of Instruments and Data Analysis - I (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 10 - Performance Characteristics of Instruments and Data Analysis - I (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 11 - Performance Characteristics of Instruments and Data Analysis - II |
Link |
NOC:Chemical Process Instrumentation |
Lecture 12 - Performance Characteristics of Instruments and Data Analysis - II (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 13 - Performance Characteristics of Instruments and Data Analysis - II (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 14 - Performance Characteristics of Instruments and Data Analysis - II (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 15 - Performance Characteristics of Instruments and Data Analysis - II (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 16 - Transducer Elements |
Link |
NOC:Chemical Process Instrumentation |
Lecture 17 - Transducer Elements (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 18 - Transducer Elements (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 19 - Transducer Elements (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 20 - Transducer Elements (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 21 - Pressure Measurement: Moderate and High Pressure Measuring Instruments |
Link |
NOC:Chemical Process Instrumentation |
Lecture 22 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 23 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 24 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 25 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 26 - High Vacuum Measurement |
Link |
NOC:Chemical Process Instrumentation |
Lecture 27 - High Vacuum Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 28 - High Vacuum Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 29 - High Vacuum Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 30 - Pressure Measurement |
Link |
NOC:Chemical Process Instrumentation |
Lecture 31 - Temperature Measurement |
Link |
NOC:Chemical Process Instrumentation |
Lecture 32 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 33 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 34 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 35 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 36 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 37 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 38 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 39 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 40 - Temperature Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 41 - Flow Measurement |
Link |
NOC:Chemical Process Instrumentation |
Lecture 42 - Flow Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 43 - Flow Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 44 - Flow Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 45 - Flow Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 46 - Level Measurement |
Link |
NOC:Chemical Process Instrumentation |
Lecture 47 - Level Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 48 - Level Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 49 - Level Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 50 - Level Measurement (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 51 - Miscellaneous Measurements : Composition |
Link |
NOC:Chemical Process Instrumentation |
Lecture 52 - Miscellaneous Measurements : Composition (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 53 - Miscellaneous Measurements : Composition (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 54 - Miscellaneous Measurements : Composition (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 55 - Miscellaneous Measurements : Composition (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 56 - Pneumatic Control Valve |
Link |
NOC:Chemical Process Instrumentation |
Lecture 57 - Pneumatic Control Valve (Continued...) |
Link |
NOC:Chemical Process Instrumentation |
Lecture 58 - Pneumatic Control Valve (Continued...) and P&ID |
Link |
NOC:Chemical Process Instrumentation |
Lecture 59 - GATE Questions |
Link |
NOC:Chemical Process Instrumentation |
Lecture 60 - GATE Questions (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 1 - Introduction to Optimization |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 2 - Introduction to Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 3 - Introduction to Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 4 - Introduction of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 5 - Introduction of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 6 - Optimization Problem Formulation |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 7 - Optimization Problem Formulation (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 8 - Optimization Problem Formulation (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 9 - Optimization Problem Formulation (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 10 - Optimization Problem Formulation (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 11 - Basic Concepts of Optimization - I |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 12 - Basic Concepts of Optimization - I (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 13 - Basic Concepts of Optimization - I (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 14 - Basic Concepts of Optimization - I (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 15 - Basic Concepts of Optimization - I (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 16 - Basic Concepts of Optimization - II |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 17 - Basic Concepts of Optimization - II (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 18 - Basic Concepts of Optimization - II (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 19 - Basic Concepts of Optimization - II (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 20 - Basic Concepts of Optimization - II (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 21 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 22 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 23 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 24 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 25 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 26 - Unconstrained Multivariable Optimization: Direct Search Methods |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 27 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 28 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 29 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 30 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 31 - Unconstrained Multivariable Optimization: Gradient Based Methods |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 32 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 33 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 34 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 35 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 36 - Introduction to Linear Programming |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 37 - Introduction to Linear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 38 - Introduction to Linear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 39 - Introduction to Linear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 40 - Introduction to Linear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 41 - Linear Programming - The Simplex Method |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 42 - Linear Programming - The Simplex Method (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 43 - Linear Programming - The Simplex Method (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 44 - Linear Programming - The Simplex Method (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 45 - Linear Programming - The Simplex Method (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 46 - Constrained Nonlinear Programming |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 47 - Constrained Nonlinear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 48 - Constrained Nonlinear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 49 - Constrained Nonlinear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 50 - Constrained Nonlinear Programming (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 51 - Applications of Optimization |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 52 - Applications of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 53 - Applications of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 54 - Applications of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 55 - Applications of Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 56 - Software Tools for Optimization |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 57 - Software Tools for Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 58 - Software Tools for Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 59 - Software Tools for Optimization (Continued...) |
Link |
NOC:Optimization in Chemical Engineering |
Lecture 60 - Software Tools for Optimization (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 1 - Introduction to Heat Transfer |
Link |
NOC:Heat Transfer (2018) |
Lecture 2 - Introduction to Heat Transfer |
Link |
NOC:Heat Transfer (2018) |
Lecture 3 - Heat Diffusion Equation |
Link |
NOC:Heat Transfer (2018) |
Lecture 4 - Relevant Boundary Conditions in Conduction |
Link |
NOC:Heat Transfer (2018) |
Lecture 5 - One Dimensional Steady State Conduction |
Link |
NOC:Heat Transfer (2018) |
Lecture 6 - Temperature Distribution in Radial Systems |
Link |
NOC:Heat Transfer (2018) |
Lecture 7 - Tutorial Problem on Critical Insulation Thickness |
Link |
NOC:Heat Transfer (2018) |
Lecture 8 - Heat Source Systems |
Link |
NOC:Heat Transfer (2018) |
Lecture 9 - Tutorial Problems of Heat Generating Systems |
Link |
NOC:Heat Transfer (2018) |
Lecture 10 - Transient Conduction |
Link |
NOC:Heat Transfer (2018) |
Lecture 11 - Lumped Capacitance (Continued...) and Tutorial Problem |
Link |
NOC:Heat Transfer (2018) |
Lecture 12 - Transient heat Conduction |
Link |
NOC:Heat Transfer (2018) |
Lecture 13 - Transient Conduction - Heisler Chart |
Link |
NOC:Heat Transfer (2018) |
Lecture 14 - Heat Transfer from Extended Surface |
Link |
NOC:Heat Transfer (2018) |
Lecture 15 - Fins and General Conduction Analysis |
Link |
NOC:Heat Transfer (2018) |
Lecture 16 - Fundamentals of Convection |
Link |
NOC:Heat Transfer (2018) |
Lecture 17 - Equations of Change for Non-isothermal Systems |
Link |
NOC:Heat Transfer (2018) |
Lecture 18 - Equations of Change for Non-isothermal Systems (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 19 - Tutorial on the Application of Energy Equation |
Link |
NOC:Heat Transfer (2018) |
Lecture 20 - Nusselt Number of a heated sphere in Stagnant Air |
Link |
NOC:Heat Transfer (2018) |
Lecture 21 - Momentum and Thermal Boundary Layers |
Link |
NOC:Heat Transfer (2018) |
Lecture 22 - The Flat Plate in Parallel Flow - Hydrodynamics and Momentum Transfer |
Link |
NOC:Heat Transfer (2018) |
Lecture 23 - The Flat Plate in Parallel Flow - Heat Transfer |
Link |
NOC:Heat Transfer (2018) |
Lecture 24 - The Effects of Turbulence |
Link |
NOC:Heat Transfer (2018) |
Lecture 25 - Turbulent External Flow |
Link |
NOC:Heat Transfer (2018) |
Lecture 26 - Heat and Momentum Transfer Analogy |
Link |
NOC:Heat Transfer (2018) |
Lecture 27 - Mixed Boundary Layers |
Link |
NOC:Heat Transfer (2018) |
Lecture 28 - Tutorial Problem on External Flow and Behavior of Heat Transfer Coefficient |
Link |
NOC:Heat Transfer (2018) |
Lecture 29 - Tutorial Problem in External Flow and Convection |
Link |
NOC:Heat Transfer (2018) |
Lecture 30 - Tutorial Problem in External Flow and Convection |
Link |
NOC:Heat Transfer (2018) |
Lecture 31 - Tutorial Problem in External Flow and Convection |
Link |
NOC:Heat Transfer (2018) |
Lecture 32 - Internal Flow Heat Transfer |
Link |
NOC:Heat Transfer (2018) |
Lecture 33 - Internal Flow Heat Transfer (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 34 - Internal Flow Heat Transfer (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 35 - Internal Flow and Heat Transfer (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 36 - Internal Flow and Heat Transfer (Tutorial) |
Link |
NOC:Heat Transfer (2018) |
Lecture 37 - Free Convection |
Link |
NOC:Heat Transfer (2018) |
Lecture 38 - Heat Exchangers |
Link |
NOC:Heat Transfer (2018) |
Lecture 39 - Heat Exchangers |
Link |
NOC:Heat Transfer (2018) |
Lecture 40 - Heat Exchangers |
Link |
NOC:Heat Transfer (2018) |
Lecture 41 - Tutorial Problems on Heat Exchanger Calculations |
Link |
NOC:Heat Transfer (2018) |
Lecture 42 - Tutorial Problem on LMTD and Dirt Factor |
Link |
NOC:Heat Transfer (2018) |
Lecture 43 - Epsilon-NTU Method - 1 |
Link |
NOC:Heat Transfer (2018) |
Lecture 44 - Epsilon-NTU Method - 1 (Continued...) |
Link |
NOC:Heat Transfer (2018) |
Lecture 45 - Tutorial Problems on Epsilon - NTU Methods |
Link |
NOC:Heat Transfer (2018) |
Lecture 46 - Tutorial Problems on Epsilon - NTU Methods |
Link |
NOC:Heat Transfer (2018) |
Lecture 47 - Boiling, Evaporation and Evaporators |
Link |
NOC:Heat Transfer (2018) |
Lecture 48 - Radiation - Fundamental Concepts |
Link |
NOC:Heat Transfer (2018) |
Lecture 49 - Spectral Blackbody Radiation Intesity and Emissive Power |
Link |
NOC:Heat Transfer (2018) |
Lecture 50 - Wein's Law, Stephen Boltzmann Law, Blackbody Radiation Function, Tutorial Problem |
Link |
NOC:Heat Transfer (2018) |
Lecture 51 - Kirchhoff's Law |
Link |
NOC:Heat Transfer (2018) |
Lecture 52 - Tutorial on Emissivity, Absroptivity and Blackbody Radiation Functions |
Link |
NOC:Heat Transfer (2018) |
Lecture 53 - Solar Radiation and the Concept of View Factors |
Link |
NOC:Heat Transfer (2018) |
Lecture 54 - Determination of View Factors |
Link |
NOC:Heat Transfer (2018) |
Lecture 55 - Radiosity Blackbody Radiation Exchanges, Relevant Problem |
Link |
NOC:Heat Transfer (2018) |
Lecture 56 - Network Method for Radiation Exchange in an Enclosure |
Link |
NOC:Heat Transfer (2018) |
Lecture 57 - Network Method - Two and Three Zone Enclosures |
Link |
NOC:Heat Transfer (2018) |
Lecture 58 - Tutorial Problem on Radiation Exhange using the Network Method |
Link |
NOC:Heat Transfer (2018) |
Lecture 59 - Radiation Shields |
Link |
NOC:Heat Transfer (2018) |
Lecture 60 - Gaseous Radiation (Participating Medium) |
Link |
NOC:Flow through Porous Media |
Lecture 1 - Introduction (Definition Of Porous Media) |
Link |
NOC:Flow through Porous Media |
Lecture 2 - Introduction (Conceptual Flow Models) |
Link |
NOC:Flow through Porous Media |
Lecture 3 - Introduction (Applications) |
Link |
NOC:Flow through Porous Media |
Lecture 4 - Mass Continuity (Introduction) |
Link |
NOC:Flow through Porous Media |
Lecture 5 - Mass Continuity (Cartesian Coordinates) |
Link |
NOC:Flow through Porous Media |
Lecture 6 - Mass Continuity (Cylindrical Coordinates) |
Link |
NOC:Flow through Porous Media |
Lecture 7 - Mass Continuity (Radial Flow) |
Link |
NOC:Flow through Porous Media |
Lecture 8 - Mass Continuity (Non-Uniform Permeability) |
Link |
NOC:Flow through Porous Media |
Lecture 9 - Mass Continuity (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 10 - Mass Continuity (Streamlines And Potential Lines) |
Link |
NOC:Flow through Porous Media |
Lecture 11 - Mass Continuity (Elementary Flow) |
Link |
NOC:Flow through Porous Media |
Lecture 12 - Mass Continuity (Source/Sink) |
Link |
NOC:Flow through Porous Media |
Lecture 13 - Mass Continuity (Superposition Of Elementary Flow) |
Link |
NOC:Flow through Porous Media |
Lecture 14 - Mass Continuity (Superposition Of Elementary Flow) (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 15 - Transport Mechanisms (Introduction) |
Link |
NOC:Flow through Porous Media |
Lecture 16 - Transport Mechanisms (Combined Mode) |
Link |
NOC:Flow through Porous Media |
Lecture 17 - Transport Mechanisms (Adsorption/Pore Condensation) |
Link |
NOC:Flow through Porous Media |
Lecture 18 - Transport Mechanisms (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 19 - Flow Equation (Introduction) |
Link |
NOC:Flow through Porous Media |
Lecture 20 - Flow Equations (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 21 - Flow Equations (Viscous Flow in Capillary) |
Link |
NOC:Flow through Porous Media |
Lecture 22 - Flow Equations (Packed Bed) |
Link |
NOC:Flow through Porous Media |
Lecture 23 - Flow Equations (Fluidized Bed) |
Link |
NOC:Flow through Porous Media |
Lecture 24 - Miscible Displacement (Uniform Velocity Over Capillary Cross-Section) |
Link |
NOC:Flow through Porous Media |
Lecture 25 - Miscible Displacement (Laminar Flow in Capillary) |
Link |
NOC:Flow through Porous Media |
Lecture 26 - Miscible Displacement (Movement of Concentration Pulse) |
Link |
NOC:Flow through Porous Media |
Lecture 27 - Miscible Displacement (Step Change in Concentration) |
Link |
NOC:Flow through Porous Media |
Lecture 28 - Miscible Displacement (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 29 - Miscible Displacement (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 30 - Miscible Displacement (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 31 - Miscible Displacement (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 32 - Miscible Displacement (Fractured Porous Media) |
Link |
NOC:Flow through Porous Media |
Lecture 33 - Miscible Displacement (Viscous Front) |
Link |
NOC:Flow through Porous Media |
Lecture 34 - Immiscible Flow |
Link |
NOC:Flow through Porous Media |
Lecture 35 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 36 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 37 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 38 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 39 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 40 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 41 - IMMISCIBLE FLOW (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 42 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 43 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 44 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 45 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 46 - Immiscible Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 47 - Interception Of Suspended Solids |
Link |
NOC:Flow through Porous Media |
Lecture 48 - Interception Of Suspended Solids (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 49 - Interception Of Suspended Solids (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 50 - Interception Of Suspended Solids (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 51 - Interception Of Suspended Solids (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 52 - Interception Of Suspended Solids (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 53 - Deformable Porous Media |
Link |
NOC:Flow through Porous Media |
Lecture 54 - Deformable Porous Media (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 55 - Deformable Porous Media (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 56 - Heat Transfer With Fluid Flow |
Link |
NOC:Flow through Porous Media |
Lecture 57 - Heat Transfer With Fluid Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 58 - Heat Transfer With Fluid Flow (Continued...) |
Link |
NOC:Flow through Porous Media |
Lecture 59 - Characterization |
Link |
NOC:Flow through Porous Media |
Lecture 60 - Characterization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 1 - Solid particle characterization |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 2 - Solid particle characterization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 3 - Particle size distribution |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 4 - Particle size distribution (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 5 - Particle size distribution (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 6 - Fluid - particle mechanics |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 7 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 8 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 9 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 10 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 11 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 12 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 13 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 14 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 15 - Fluid - particle mechanics (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 16 - Flow through packed beds |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 17 - Flow through packed beds (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 18 - Flow through packed beds (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 19 - Flow through packed beds (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 20 - Flow through packed beds (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 21 - Fluidization |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 22 - Fluidization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 23 - Fluidization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 24 - Fluidization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 25 - Fluidization (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 26 - Sedimentation |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 27 - Sedimentation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 28 - Sedimentation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 29 - Sedimentation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 30 - Sedimentation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 31 - Filtration |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 32 - Filtration (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 33 - Filtration (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 34 - Filtration (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 35 - Filtration (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 36 - Centrifugal Separation |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 37 - Centrifugal Separation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 38 - Centrifugal Separation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 39 - Centrifugal Separation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 40 - Centrifugal Separation (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 41 - Particle size reduction |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 42 - Particle size reduction (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 43 - Particle size reduction (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 44 - Particle size reduction (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 45 - Particle size reduction (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 46 - Particle size reduction (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 47 - Particle size enlargement |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 48 - Particle size enlargement (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 49 - Particle size enlargement (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 50 - Particle size enlargement (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 51 - Fluid - solid transport |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 52 - Fluid - solid transport (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 53 - Fluid - solid transport (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 54 - Fluid - solid transport (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 55 - Fluid - solid transport (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 56 - Colloids and nanoparticles |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 57 - Colloids and nanoparticles (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 58 - Colloids and nanoparticles (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 59 - Colloids and nanoparticles (Continued...) |
Link |
NOC:Fundamentals of Particle and Fluid Solid Processing |
Lecture 60 - Colloids and nanoparticles (Continued...) |
Link |
NOC:Plant Design and Economics |
Lecture 1 - Introduction |
Link |
NOC:Plant Design and Economics |
Lecture 2 - Typical Design Steps |
Link |
NOC:Plant Design and Economics |
Lecture 3 - Flow Diagram |
Link |
NOC:Plant Design and Economics |
Lecture 4 - Flow Diagram - Mass and Energy Balance |
Link |
NOC:Plant Design and Economics |
Lecture 5 - Piping and Instrumentation Diagram |
Link |
NOC:Plant Design and Economics |
Lecture 6 - Selection of Process Equipment |
Link |
NOC:Plant Design and Economics |
Lecture 7 - Process Utilities |
Link |
NOC:Plant Design and Economics |
Lecture 8 - Plant Location |
Link |
NOC:Plant Design and Economics |
Lecture 9 - Site and Plant Layout |
Link |
NOC:Plant Design and Economics |
Lecture 10 - Heuristics in Process Synthesis and Design |
Link |
NOC:Plant Design and Economics |
Lecture 11 - Capital Investment |
Link |
NOC:Plant Design and Economics |
Lecture 12 - Capital Cost Estimates |
Link |
NOC:Plant Design and Economics |
Lecture 13 - Cost Components in Capital Investments |
Link |
NOC:Plant Design and Economics |
Lecture 14 - Methods of Capital Cost Estimates |
Link |
NOC:Plant Design and Economics |
Lecture 15 - Estimation of Total Product Cost |
Link |
NOC:Plant Design and Economics |
Lecture 16 - Different Types of Interest |
Link |
NOC:Plant Design and Economics |
Lecture 17 - Continuous Interest, Cash Flow Diagram, Time Value of Money |
Link |
NOC:Plant Design and Economics |
Lecture 18 - Uniform Cash Flows and Continuous Flows |
Link |
NOC:Plant Design and Economics |
Lecture 19 - Income Tax and Depreciation |
Link |
NOC:Plant Design and Economics |
Lecture 20 - Depreciation |
Link |
NOC:Plant Design and Economics |
Lecture 21 - Cumulative Cash Flow and Profitability Standards |
Link |
NOC:Plant Design and Economics |
Lecture 22 - Profitability Analysis |
Link |
NOC:Plant Design and Economics |
Lecture 23 - Profitability Analysis (Continued...) |
Link |
NOC:Plant Design and Economics |
Lecture 24 - Profitability Analysis (Continued...) |
Link |
NOC:Plant Design and Economics |
Lecture 25 - Alternative Investment, Replacement and Sensitivity Analysis |
Link |
NOC:Plant Design and Economics |
Lecture 26 - Introduction to Process Synthesis |
Link |
NOC:Plant Design and Economics |
Lecture 27 - Hierarchical Approach to Process Synthesis - I |
Link |
NOC:Plant Design and Economics |
Lecture 28 - Hierarchical Approach to Process Synthesis - II |
Link |
NOC:Plant Design and Economics |
Lecture 29 - Hierarchical Approach to Process Synthesis - III |
Link |
NOC:Plant Design and Economics |
Lecture 30 - Hierarchical Approach to Process Synthesis - IV |
Link |
NOC:Plant Design and Economics |
Lecture 31 - Basic Reactor Principles |
Link |
NOC:Plant Design and Economics |
Lecture 32 - Reactor Synthesis for Complex Reactions by Attainable Region: Fundamentals |
Link |
NOC:Plant Design and Economics |
Lecture 33 - Reactor Synthesis for Complex Reactions by Attainable Region: Example-1 |
Link |
NOC:Plant Design and Economics |
Lecture 34 - Reactor Synthesis for Complex Reactions by Attainable Region: Example-2 |
Link |
NOC:Plant Design and Economics |
Lecture 35 - General Procedure for Reactor Design and Cost Estimation |
Link |
NOC:Plant Design and Economics |
Lecture 36 - Introduction to Separation Systems |
Link |
NOC:Plant Design and Economics |
Lecture 37 - Selection Criteria for Separation Processes |
Link |
NOC:Plant Design and Economics |
Lecture 38 - Design of Multi-component Distillation Column: Short Cut Method |
Link |
NOC:Plant Design and Economics |
Lecture 39 - Design of Multi-component Distillation Column: Short Cut Method - Example |
Link |
NOC:Plant Design and Economics |
Lecture 40 - Introduction to Sequencing of Ordinary Distillation Columns |
Link |
NOC:Plant Design and Economics |
Lecture 41 - Sequences for Simple Nonintegrated Distillation Columns |
Link |
NOC:Plant Design and Economics |
Lecture 42 - Distillation Sequencing using Columns with Sidestreams |
Link |
NOC:Plant Design and Economics |
Lecture 43 - Distillation Sequencing using Thermal Coupling |
Link |
NOC:Plant Design and Economics |
Lecture 44 - Azeotropic Distillation: Residue Curve Maps |
Link |
NOC:Plant Design and Economics |
Lecture 45 - Azeotropic Distillation Methods and Cost Estimation |
Link |
NOC:Plant Design and Economics |
Lecture 46 - Introduction to Pinch Technology |
Link |
NOC:Plant Design and Economics |
Lecture 47 - Composite Curves |
Link |
NOC:Plant Design and Economics |
Lecture 48 - The Problem Table Method |
Link |
NOC:Plant Design and Economics |
Lecture 49 - The Heat Recovery Pinch and The Grand Composite Curve |
Link |
NOC:Plant Design and Economics |
Lecture 50 - Heat Exchanger Network Design |
Link |
NOC:Plant Design and Economics |
Lecture 51 - Introduction |
Link |
NOC:Plant Design and Economics |
Lecture 52 - Fires and Explosions: Flammability Characteristics |
Link |
NOC:Plant Design and Economics |
Lecture 53 - Fires and Explosions: Prevention |
Link |
NOC:Plant Design and Economics |
Lecture 54 - Toxic Release, Hazard Identification and MSDS |
Link |
NOC:Plant Design and Economics |
Lecture 55 - Inherently Safer Design |
Link |
NOC:Plant Design and Economics |
Lecture 56 - Optimality Criteria for Unconstrained Functions |
Link |
NOC:Plant Design and Economics |
Lecture 57 - Examples |
Link |
NOC:Plant Design and Economics |
Lecture 58 - Equality Constrained Problems: Langrange Multipliers |
Link |
NOC:Plant Design and Economics |
Lecture 59 - Linear Programming Problems |
Link |
NOC:Plant Design and Economics |
Lecture 60 - Batch Process Scheduling |
Link |
NOC:Colloids and Surfaces |
Lecture 1 - Introduction and motivation |
Link |
NOC:Colloids and Surfaces |
Lecture 2 - Colloidal dispersions, terminology and classification |
Link |
NOC:Colloids and Surfaces |
Lecture 3 - Stability in colloids |
Link |
NOC:Colloids and Surfaces |
Lecture 4 - Source, synthesis and characterisation of colloids |
Link |
NOC:Colloids and Surfaces |
Lecture 5 - Characterisation of colloidal particles - I |
Link |
NOC:Colloids and Surfaces |
Lecture 6 - Characterisation of colloidal particles - II |
Link |
NOC:Colloids and Surfaces |
Lecture 7 - Introduction to forces acting on an individual colloidal particle |
Link |
NOC:Colloids and Surfaces |
Lecture 8 - Introduction to interaction between colloidal particles |
Link |
NOC:Colloids and Surfaces |
Lecture 9 - Application of Brownian force: Measument of diffusivity and size |
Link |
NOC:Colloids and Surfaces |
Lecture 10 - Radiation used to study colloidal systems |
Link |
NOC:Colloids and Surfaces |
Lecture 11 - Radiation used to study colloidal systems |
Link |
NOC:Colloids and Surfaces |
Lecture 12 - Molecular origin of Van der waals forces |
Link |
NOC:Colloids and Surfaces |
Lecture 13 - Vanderwaal interactions between particles |
Link |
NOC:Colloids and Surfaces |
Lecture 14 - Problem on scaling of Vanderwaal interactions |
Link |
NOC:Colloids and Surfaces |
Lecture 15 - Calculation of Vanderwaal's forces between semi-infinite blocks and Hamaker constant - I |
Link |
NOC:Colloids and Surfaces |
Lecture 16 - Calculation of Vanderwaal's forces between semi-infinite blocks and Hamaker constant - II |
Link |
NOC:Colloids and Surfaces |
Lecture 17 - Theories of Vanderwaal forces based on bulk properties and calculation of Hamaker constant using bulk properties |
Link |
NOC:Colloids and Surfaces |
Lecture 18 - Effect of medium on Vanderwaal's interactions - I |
Link |
NOC:Colloids and Surfaces |
Lecture 19 - Effect of medium on Vanderwaal's interactions - II |
Link |
NOC:Colloids and Surfaces |
Lecture 20 - Colloid Polymer mixtures |
Link |
NOC:Colloids and Surfaces |
Lecture 21 - Colloid polymer mixtures: colloid-solvent interactions and colloid-polymer interactions |
Link |
NOC:Colloids and Surfaces |
Lecture 22 - Colloid polymer mixtures: Depletion flocculation |
Link |
NOC:Colloids and Surfaces |
Lecture 23 - Colloid polymer mixtures: Depletion stabilisation |
Link |
NOC:Colloids and Surfaces |
Lecture 24 - Depletion interactions |
Link |
NOC:Colloids and Surfaces |
Lecture 25 - Steric interactions/osmotic repulsion |
Link |
NOC:Colloids and Surfaces |
Lecture 26 - Tutorial problem on depletion interactions |
Link |
NOC:Colloids and Surfaces |
Lecture 27 - Colloidal Interactions: Introduction to electrostatic interactions/electrical double layer interactions |
Link |
NOC:Colloids and Surfaces |
Lecture 28 - Introduction to models of electrical double layer: Helmholtz model/capacitor model |
Link |
NOC:Colloids and Surfaces |
Lecture 29 - Review and summary of Helmholtz model (or capacitor model) of electrical double layer |
Link |
NOC:Colloids and Surfaces |
Lecture 30 - Models of electrical double layer: Diffuse double layer model/Gouy-Chapman model |
Link |
NOC:Colloids and Surfaces |
Lecture 31 - Potential distribution near planar surfaces: Derivation of the Poisson-Boltzmann equation |
Link |
NOC:Colloids and Surfaces |
Lecture 32 - Potential distribution near planar surfaces: Solution to the linearised Poisson-Boltzmann equation |
Link |
NOC:Colloids and Surfaces |
Lecture 33 - Potential distribution near spherical surfaces: Solution to linearised Poisson-Boltzmann equation |
Link |
NOC:Colloids and Surfaces |
Lecture 34 - Comparison of Capacitor model and Diffuse double layer model |
Link |
NOC:Colloids and Surfaces |
Lecture 35 - Models of electrical double layer: Gouy Chapman Theory - I |
Link |
NOC:Colloids and Surfaces |
Lecture 36 - Models of electrical double layer: Gouy Chapman Theory - II |
Link |
NOC:Colloids and Surfaces |
Lecture 37 - Structure of Electrical double layer |
Link |
NOC:Colloids and Surfaces |
Lecture 38 - Force of Repulsion between interacting surfaces |
Link |
NOC:Colloids and Surfaces |
Lecture 39 - Potential Energy of repulsion between Planar double layers and DLVO Theory |
Link |
NOC:Colloids and Surfaces |
Lecture 40 - Zeta Potential and Electrophoretic mobility of an ion |
Link |
NOC:Colloids and Surfaces |
Lecture 41 - Electrokinetic Phenomena |
Link |
NOC:Colloids and Surfaces |
Lecture 42 - Relation between Electrophoretic mobility and Zeta potential - I |
Link |
NOC:Colloids and Surfaces |
Lecture 43 - Relation between Electrophoretic mobility and Zeta potential - II |
Link |
NOC:Colloids and Surfaces |
Lecture 44 - Colloidal particles at interfaces:Introduction |
Link |
NOC:Colloids and Surfaces |
Lecture 45 - Characterization of Particles at interface |
Link |
NOC:Colloids and Surfaces |
Lecture 46 - Experimental Observations -Concept of Electrostatic interactions and Stability at interfaces |
Link |
NOC:Colloids and Surfaces |
Lecture 47 - Implications from Surface energy balances and Estimation of energy required for detachment |
Link |
NOC:Colloids and Surfaces |
Lecture 48 - Colloidal interactions at interface |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 1 - Why are polymers so common? |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 2 - Polymers: Molecular structure |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 3 - Process, structure, property |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 4 - Biopolymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 5 - Molecular weight and distribution |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 6 - Polymerization |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 7 - Macromolecular nature |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 8 - Renewable sources for polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 9 - Polymerization/depolymerization |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 10 - States of interest |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 11 - Application based terms |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 12 - Reuse and repurpose |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 13 - Molecular conformations |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 14 - Size, mobility and flexibility |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 15 - Polyelectrolytes |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 16 - Structures in biopolymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 17 - Amorphous/crystalline states - 1 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 18 - Amorphous/crystalline states - 2 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 19 - Orientation |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 20 - Interactions |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 21 - Kinetics of crystallization |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 22 - Glass transition - 1 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 23 - Glass transition - 2 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 24 - States in environment |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 25 - Liquid crystalline polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 26 - Copolymers - 1 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 27 - Copolymers - 2 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 28 - Blends - 1 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 29 - Blends - 2 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 30 - Microstructure in polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 31 - Composites |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 32 - Stress strain response |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 33 - Additives for polymeric systems |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 34 - Blends/composites in recycling |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 35 - Physical/chemical crosslinking |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 36 - Mechanical properties - I |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 37 - Mechanical properties - II |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 38 - Physical and chemical aging |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 39 - Solutions: properties |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 40 - Conducting polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 41 - Dielectric response - I |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 42 - Dielectric response - II |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 43 - Plasticity |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 44 - Properties of composites |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 45 - Viscoelasticity: introduction |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 46 - Thermal response |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 47 - Viscoelasticity: characterization |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 48 - Viscoelasticity: simple models |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 49 - Dynamic Mechanical analysis |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 50 - Damping Applications |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 51 - Time Temperature superposition |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 52 - Impact and energy absorption |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 53 - Testing for applications |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 54 - Properties of blends |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 55 - Biomimetic polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 56 - Advanced mechanics |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 57 - Viscoelastic response: examples |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 58 - Polymer packaging |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 59 - Porous polymers/membranes |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 60 - Polymer at interfaces |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 61 - Diffusion in polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 62 - Compatibilizers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 63 - Biopolymer applications |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 64 - Adhesives and Paints |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 65 - Dissolution and recovery |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 66 - Polymerization kinetics |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 67 - Polymerization reactors |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 68 - Polymer processing - I |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 69 - Polymer processing - II |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 70 - Polymer processing - III |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 71 - Flow simulations |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 72 - Processing for recycling |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 73 - Recycle, up-down cycling - I |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 74 - Recycle, up-down cycling - II |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 75 - Flow behaviour - rheology |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 76 - Crosslinking |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 77 - Conversion of polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 78 - Rheology and entanglement |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 79 - Rheological models |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 80 - Rheology and processing |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 81 - Absorption and leaching |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 82 - Swelling of polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 83 - Viscosity for polymer processing |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 84 - Microplastics, aerosols, sediments |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 85 - Biodegradation of polymers |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 86 - Biodegradable polymers - 1 |
Link |
NOC:Polymers: Concepts, Properties, Uses and Sustainability |
Lecture 87 - Biodegradable polymers - 2 |
Link |
NOC:Material and Energy Balance Computations |
Lecture 1 - Introduction to Engineering Calculations |
Link |
NOC:Material and Energy Balance Computations |
Lecture 2 - Introduction to Engineering Calculations (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 3 - Introduction to Engineering Calculations (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 4 - Introduction to Processes and Process Variables |
Link |
NOC:Material and Energy Balance Computations |
Lecture 5 - Introduction to Processes and Process Variables (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 6 - Fundamentals of Material Balance |
Link |
NOC:Material and Energy Balance Computations |
Lecture 7 - Fundamentals of Material Balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 8 - Fundamentals of Material Balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 9 - Fundamentals of Material Balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 10 - Material Balance of Single-unit |
Link |
NOC:Material and Energy Balance Computations |
Lecture 11 - Material Balance of Multiple Units |
Link |
NOC:Material and Energy Balance Computations |
Lecture 12 - Material Balance of Multiple Units (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 13 - Material Balance of Multiple Units (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 14 - Material Balance of Multiple Units (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 15 - Material Balance of Multiple Units - Recycle |
Link |
NOC:Material and Energy Balance Computations |
Lecture 16 - Material Balance of Recycle and Bypass Units |
Link |
NOC:Material and Energy Balance Computations |
Lecture 17 - Material Balance of Recycle and Bypass Units (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 18 - Introduction |
Link |
NOC:Material and Energy Balance Computations |
Lecture 19 - Introduction (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 20 - Introduction (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 21 - Multiple reactions and reactive process balance |
Link |
NOC:Material and Energy Balance Computations |
Lecture 22 - Reactive process balance |
Link |
NOC:Material and Energy Balance Computations |
Lecture 23 - Multiple reactions and reactive process balance |
Link |
NOC:Material and Energy Balance Computations |
Lecture 24 - Reactive process balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 25 - Reactive process balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 26 - Combustion reactions balance |
Link |
NOC:Material and Energy Balance Computations |
Lecture 27 - Combustion reactions balance (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 28 - Single-phase systems |
Link |
NOC:Material and Energy Balance Computations |
Lecture 29 - Single phase systems (Continued...) |
Link |
NOC:Material and Energy Balance Computations |
Lecture 30 - Single-phase problems and concept of multi-phase system |
Link |
NOC:Material and Energy Balance Computations |
Lecture 31 - Introduction to Energy Balance - I |
Link |
NOC:Material and Energy Balance Computations |
Lecture 32 - Introduction to Energy Balance - II |
Link |
NOC:Material and Energy Balance Computations |
Lecture 33 - Introduction to Energy Balance - III |
Link |
NOC:Material and Energy Balance Computations |
Lecture 34 - Introduction to Energy Balance - IV |
Link |
NOC:Material and Energy Balance Computations |
Lecture 35 - Introduction to Energy Balance - V |
Link |
NOC:Material and Energy Balance Computations |
Lecture 36 - Introduction to Energy Balance - VI |
Link |
NOC:Material and Energy Balance Computations |
Lecture 37 - Introduction to Energy Balance - VII |
Link |
NOC:Material and Energy Balance Computations |
Lecture 38 - Introduction to Energy Balance - VIII |
Link |
NOC:Material and Energy Balance Computations |
Lecture 39 - Introduction to Energy Balance - IX |
Link |
NOC:Material and Energy Balance Computations |
Lecture 40 - Introduction to Energy Balance - X |
Link |
NOC:Material and Energy Balance Computations |
Lecture 41 - Introduction to Energy Balance - XI |
Link |
NOC:Material and Energy Balance Computations |
Lecture 42 - Estimation of Physical Properties - I |
Link |
NOC:Material and Energy Balance Computations |
Lecture 43 - Estimation of Physical Properties - II |
Link |
NOC:Material and Energy Balance Computations |
Lecture 44 - Estimation of Physical Properties - III |
Link |
NOC:Material and Energy Balance Computations |
Lecture 45 - Tutorial - I |
Link |
NOC:Material and Energy Balance Computations |
Lecture 46 - Tutorial - II |
Link |
NOC:Material and Energy Balance Computations |
Lecture 47 - Tutorial - III |
Link |
NOC:Material and Energy Balance Computations |
Lecture 48 - Tutorial - IV |
Link |
NOC:Material and Energy Balance Computations |
Lecture 49 - Estimation of Physical Parameters - IV |
Link |
NOC:Material and Energy Balance Computations |
Lecture 50 - Estimation of Physical Parameters - V |
Link |
NOC:Material and Energy Balance Computations |
Lecture 51 - Energy Balance with Chemical Reactions - I |
Link |
NOC:Material and Energy Balance Computations |
Lecture 52 - Energy Balance with Chemical Reactions - II |
Link |
NOC:Material and Energy Balance Computations |
Lecture 53 - Energy Balance with Chemical Reactions - III |
Link |
NOC:Material and Energy Balance Computations |
Lecture 54 - Energy Balance with Chemical Reactions - IV |
Link |
NOC:Material and Energy Balance Computations |
Lecture 55 - Energy Balance with Chemical Reactions - V |
Link |
NOC:Material and Energy Balance Computations |
Lecture 56 - Energy Balance with Chemical Reactions - VI |
Link |
NOC:Material and Energy Balance Computations |
Lecture 57 - Humidity and Psychrometric Chart - I |
Link |
NOC:Material and Energy Balance Computations |
Lecture 58 - Humidity and Psychrometric Chart - II |
Link |
NOC:Material and Energy Balance Computations |
Lecture 59 - Humidity and Psychrometric Chart - III |
Link |
NOC:Material and Energy Balance Computations |
Lecture 60 - Humidity and Psychrometric Chart - IV |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 1 - Introduction |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 2 - Introduction (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 3 - Optimum design and design documentation |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 4 - Introduction to Mass Transfer Processes |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 5 - Phase Equillibrium |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 6 - Phase Equillibrium (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 7 - Phase Equillibrium (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 8 - Distillation |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 9 - Flash Distillation and Design problem |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 10 - Fractionation |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 11 - Fractionation (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 12 - McCabe-Thiele construction for number of ideal stages |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 13 - Optimum Design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 14 - Multi-component fractionation design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 15 - Batch Distillation |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 16 - Practical issues in desigining distillation processes |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 17 - Design of absorbers |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 18 - Design of absorbers (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 19 - Design of absorbers (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 20 - Tower and Tower internals |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 21 - Tower and Tower internals (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 22 - Tower and Tower internals (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 23 - Sieve Tray Design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 24 - Sieve Tray Design (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 25 - Sieve Tray Design (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 26 - Bubble Cap Tray Design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 27 - Bubble Cap Tray Design (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 28 - Bubble Cap Tray Design (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 29 - Tower and Tower internals (Packed Tower Design) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 30 - Tower and Tower internals (Packed Tower Design) (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 31 - Adsorption |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 32 - Packed bed adsorption |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 33 - Packed bed adsorber design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 34 - Packed bed adsorber design (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 35 - Liquid-liquid extraction (LLE) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 36 - Liquid-liquid extraction (L2) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 37 - Liquid-liquid extraction (L3) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 38 - Liquid-liquid extraction (L4) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 39 - Liquid-liquid extraction (L5) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 40 - Design of Mass Transfer Processes (Review) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 41 - Design of Heat Transfer Processes - Introduction |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 42 - Double Pipe Heat exchanger |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 43 - Double Pipe Heat exchanger (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 44 - Double Pipe Heat exchanger (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 45 - Design of Shell and Tube Heat Exchangers - a general overview |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 46 - Design of Shell and Tube Heat Exchangers - a general overview (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 47 - Shell and Tube Heat Exchanger - Design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 48 - Shell and Tube Heat Exchanger - Design |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 49 - Heat exchanger Network Analysis |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 50 - Heat exchanger Network Analysis (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 51 - Heat exchanger Network Analysis (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 52 - Heat exchanger Network Analysis (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 53 - Heat exchanger Network Analysis (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 54 - Plant Hydraulics |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 55 - Plant Hydraulics (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 56 - Plant Hydraulics (Continued...) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 57 - Plant Hydraulics (End) |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 58 - Process Vessels |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 59 - Process Instrumentation and Control |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 60 - Engineered Safety |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 61 - Process Utilities |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 62 - Process Design using Simulators |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 63 - Process Packages |
Link |
NOC:Principles and Practices of Process Equipment and Plant Design |
Lecture 64 - Design of a 10 TPD Mono-nitrotoluene plant |
Link |
Chemical Engineering Thermodynamics |
Lecture 1 - Thermodynamics and the Chemical Industry |
Link |
Chemical Engineering Thermodynamics |
Lecture 2 - James Prescot Joule and the first law |
Link |
Chemical Engineering Thermodynamics |
Lecture 3 - Sadi Carnot and the second law |
Link |
Chemical Engineering Thermodynamics |
Lecture 4 - Equilibrium and Extrema in work |
Link |
Chemical Engineering Thermodynamics |
Lecture 5 - Illustrative Calculations - I |
Link |
Chemical Engineering Thermodynamics |
Lecture 6 - Properties of pure substances |
Link |
Chemical Engineering Thermodynamics |
Lecture 7 - The p-h chart |
Link |
Chemical Engineering Thermodynamics |
Lecture 8 - Work calculation |
Link |
Chemical Engineering Thermodynamics |
Lecture 9 - Illustrative Calculations - II |
Link |
Chemical Engineering Thermodynamics |
Lecture 10 - Heat-Work Interconversion Devices |
Link |
Chemical Engineering Thermodynamics |
Lecture 11 - Refrigeration / Thermodynamics of mixtures |
Link |
Chemical Engineering Thermodynamics |
Lecture 12 - The Gibbs Duhem equation |
Link |
Chemical Engineering Thermodynamics |
Lecture 13 - Models for Excess Gibbs Free Energy |
Link |
Chemical Engineering Thermodynamics |
Lecture 14 - Van Laar model |
Link |
Chemical Engineering Thermodynamics |
Lecture 15 - Gaseous and liquid mixtures |
Link |
Chemical Engineering Thermodynamics |
Lecture 16 - Separation Work / Equations of state |
Link |
Chemical Engineering Thermodynamics |
Lecture 17 - Chemical potentials in gas and condensed phases |
Link |
Chemical Engineering Thermodynamics |
Lecture 18 - Vapour Liquid Equilibria - I |
Link |
Chemical Engineering Thermodynamics |
Lecture 19 - Vapour Liquid Equilibria - II |
Link |
Chemical Engineering Thermodynamics |
Lecture 20 - Solvent-Solvent mixtures |
Link |
Chemical Engineering Thermodynamics |
Lecture 21 - Solvent-Solute mixtures |
Link |
Chemical Engineering Thermodynamics |
Lecture 22 - Liquid-liquid equilibria |
Link |
Chemical Engineering Thermodynamics |
Lecture 23 - An industrial example |
Link |
Chemical Engineering Thermodynamics |
Lecture 24 - Liquid-liquid equilibria / Reaction Equilibria |
Link |
Chemical Engineering Thermodynamics |
Lecture 25 - Reaction Equilibria |
Link |
Chemical Engineering Thermodynamics |
Lecture 26 - Illustrative Examples - I |
Link |
Chemical Engineering Thermodynamics |
Lecture 27 - Illustrative Examples - II |
Link |
Chemical Engineering Thermodynamics |
Lecture 28 - Illustrative Examples - III |
Link |
Chemical Engineering Thermodynamics |
Lecture 29 - Simultaneous Relations |
Link |
Chemical Engineering Thermodynamics |
Lecture 30 - Thermodynamic Consistency / Reverse Osmosis |
Link |
Chemical Engineering Thermodynamics |
Lecture 31 - Miscellaneous topics in phase equilibria |
Link |
Chemical Engineering Thermodynamics |
Lecture 32 - Absorption Refrigeration |
Link |
Chemical Engineering Thermodynamics |
Lecture 33 - Summary of Classical Thermodynamics |
Link |
Chemical Engineering Thermodynamics |
Lecture 34 - Molecular basis of Thermodynamics - I |
Link |
Chemical Engineering Thermodynamics |
Lecture 35 - Molecular basis of Thermodynamics - II |
Link |
Computational Fluid Dynamics |
Lecture 1 - Motivation for CFD and Introduction to the CFD approach |
Link |
Computational Fluid Dynamics |
Lecture 2 - Illustration of the CFD approach through a worked out example |
Link |
Computational Fluid Dynamics |
Lecture 3 - Eulerian approach, Conservation Equation, Derivation of Mass Conservation Equation and Statement of the momentum conservation equation |
Link |
Computational Fluid Dynamics |
Lecture 4 - Forces acting on a control volume; Stress tensor; Derivation of the momentum conservation equation ; Closure problem; Deformation of a fluid element in fluid flow |
Link |
Computational Fluid Dynamics |
Lecture 5 - Kinematics of deformation in fluid flow; Stress vs strain rate relation; Derivation of the Navier-Stokes equations |
Link |
Computational Fluid Dynamics |
Lecture 6 - Equations governing flow of incompressible flow; Initial and boundary conditions; Wellposedness of a fluid flow problem |
Link |
Computational Fluid Dynamics |
Lecture 7 - Equations for some simple cases; Generic scalar transport equation form of the governing equations; Outline of the approach to the solution of the N-S equations. |
Link |
Computational Fluid Dynamics |
Lecture 8 - cut out the first 30s; Spatial discretization of a simple flow domain; Taylor’s series expansion and the basis of finite difference approximation of a derivative; Central and one-sided difference approximations; Order of accuracy of finite difference ap |
Link |
Computational Fluid Dynamics |
Lecture 9 - Finite difference approximation of pth order of accuracy for qth order derivative; cross -derivatives; Examples of high order accurate formulae for several derivatives |
Link |
Computational Fluid Dynamics |
Lecture 10 - One -sided high order accurate approximations; Explicit and implicit formulations for the time derivatives |
Link |
Computational Fluid Dynamics |
Lecture 11 - Numerical solution of the unsteady advection equation using different finite difference approximations |
Link |
Computational Fluid Dynamics |
Lecture 12 - Need for analysis of a discretization scheme; Concepts of consistency, stability and convergence and the equivalence theorem of Lax ; Analysis for consistency |
Link |
Computational Fluid Dynamics |
Lecture 13 - Statement of the stability problem; von Neumann stability analysis of the first order wave equation |
Link |
Computational Fluid Dynamics |
Lecture 14 - Consistency and stability analysis of the unsteady diffusion equation; Analysis for two- and three -dimensional cases; Stability of implicit schemes |
Link |
Computational Fluid Dynamics |
Lecture 15 - Interpretation of the stability condition; Stability analysis of the generic scalar equation and the concept of upwinding ; Diffusive and dissipative errors in numerical solution; Introduction to the concept of TVD schemes |
Link |
Computational Fluid Dynamics |
Lecture 16 - Template for the generic scalar transport equation and its extension to the solution of Navier-Stokes equa tions for a compressible flow. |
Link |
Computational Fluid Dynamics |
Lecture 17 - Illustration of application of the template using the MacCormack scheme for a three-dimensional compressible flow |
Link |
Computational Fluid Dynamics |
Lecture 18 - Stability limits of MacCormack scheme; Limitations in extending compressible flow schemes to incompre ssible flows ; Difficulty of evaluation of pressure in incompressible flows and listing of various approaches |
Link |
Computational Fluid Dynamics |
Lecture 19 - Artificial compressibility method and the streamfunction-vorticity method for the solution of NS equations and their limitations |
Link |
Computational Fluid Dynamics |
Lecture 20 - Pressur e equation method for the solution of NS equations |
Link |
Computational Fluid Dynamics |
Lecture 21 - Pressure-correction approach to the solution of NS equations on a staggered grid; SIMPLE and its family of methods |
Link |
Computational Fluid Dynamics |
Lecture 22 - Need for effici ent solution of linear algebraic equations; Classification of approaches for the solution of linear algebraic equations. |
Link |
Computational Fluid Dynamics |
Lecture 23 - Direct methods for linear algebraic equations; Gaussian elimination method |
Link |
Computational Fluid Dynamics |
Lecture 24 - Gauss-Jordan method; LU decomposition method; TDMA and Thomas algorithm |
Link |
Computational Fluid Dynamics |
Lecture 25 - Basic iterative methods for linear algebraic equations: Description of point -Jacobi, Gauss-Seidel and SOR methods |
Link |
Computational Fluid Dynamics |
Lecture 26 - Convergence analysis of basic iterative schemes; Diagonal dominance condition for convergence; Influence of source terms on the diagonal dominance condition; Rate of convergence |
Link |
Computational Fluid Dynamics |
Lecture 27 - Application to the Laplace equation |
Link |
Computational Fluid Dynamics |
Lecture 28 - Advanced iterative methods: Alternating Direction Implicit Method; Operator splitting |
Link |
Computational Fluid Dynamics |
Lecture 29 - Advanced iterative methods; Strongly Implicit Proc edure; Conjugate gradient method; Multigrid method |
Link |
Computational Fluid Dynamics |
Lecture 30 - Illustration of the Multigrid method for the Laplace equation |
Link |
Computational Fluid Dynamics |
Lecture 31 - Overview of the approach of numerical solution of NS equations for simple domains; Introduction to complexity arising from physics and geometry |
Link |
Computational Fluid Dynamics |
Lecture 32 - Derivation of the energy conservation equation |
Link |
Computational Fluid Dynamics |
Lecture 33 - Derivation of the species conservation equation; dealing with chemical reactions |
Link |
Computational Fluid Dynamics |
Lecture 34 - Turbulence; Characteri stics of turbulent flow; Dealing with fluctuations and the concept of time-averaging |
Link |
Computational Fluid Dynamics |
Lecture 35 - Derivation of the Reynolds -averaged Navier -Stokes equations; identification of the closure problem of turbulence; Boussinesq hypothesis and eddy viscosity |
Link |
Computational Fluid Dynamics |
Lecture 36 - Reynol ds stresses in turbulent flow; Time and length scales of turbulence; Energy cascade; Mixing length model for eddy viscosity |
Link |
Computational Fluid Dynamics |
Lecture 37 - One-equation model for turbulent flow |
Link |
Computational Fluid Dynamics |
Lecture 38 - Two -equation model for turbulent flow; Numerical calculation of turbulent reacting flows |
Link |
Computational Fluid Dynamics |
Lecture 39 - Calculation of near-wall region in turbulent flow; wall function approach; near-wall turbulence models |
Link |
Computational Fluid Dynamics |
Lecture 40 - Need for special methods for dealing with irregular flow geometry; Outline of the Body-fitted grid approach ; Coordinate transformation to a general, 3-D curvilinear system |
Link |
Computational Fluid Dynamics |
Lecture 41 - Transformation of the governing equations; Illustration for the Laplace equation; Appearance and significance of cross -derivative terms; Concepts of structured and unstructured grids. |
Link |
Computational Fluid Dynamics |
Lecture 42 - Finite vol ume method for complicated flow domain; Illustration for the case of flow through a duct of triangular cross -section. |
Link |
Computational Fluid Dynamics |
Lecture 43 - Finite volume method for the general case |
Link |
Computational Fluid Dynamics |
Lecture 44 - Generation of a structured grid for irregular flow domain; Algebraic methods; Elliptic grid generation method |
Link |
Computational Fluid Dynamics |
Lecture 45 - Unstructured grid generation; Domain nodalization; Advancing front method for triangulation |
Link |
Computational Fluid Dynamics |
Lecture 46 - Delaunay triangulation method for unstructured grid generation |
Link |
Computational Fluid Dynamics |
Lecture 47 - Co -located grid approach for irregular geometries; Pressure correction equation for a co -located structured grid; Pressure correction equation for a co-located unstructured grid. |
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Computational Techniques |
Lecture 1 - Introduction |
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Computational Techniques |
Lecture 2 - Computational and Error Analysis |
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Computational Techniques |
Lecture 3 - Linear Equations - Part 1 |
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Computational Techniques |
Lecture 4 - Linear Equations - Part 2 |
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Computational Techniques |
Lecture 5 - Linear Equations - Part 3 |
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Computational Techniques |
Lecture 6 - Linear Equations - Part 4 |
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Computational Techniques |
Lecture 7 - Linear Equations - Part 5 |
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Computational Techniques |
Lecture 8 - Linear Equations - Part 6 |
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Computational Techniques |
Lecture 9 - Non Linear Algebraic Equations - Part 1 |
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Computational Techniques |
Lecture 10 - Non Linear Algebraic Equations - Part 2 |
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Computational Techniques |
Lecture 11 - Non Linear Algebraic Equations - Part 3 |
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Computational Techniques |
Lecture 12 - Non Linear Algebraic Equations - Part 4 |
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Computational Techniques |
Lecture 13 - Non Linear Algebraic Equations - Part 5 |
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Computational Techniques |
Lecture 14 - Non Linear Algebraic Equations - Part 6 |
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Computational Techniques |
Lecture 15 - Regression and Interpolation - Part 1 |
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Computational Techniques |
Lecture 16 - Regression and Interpolation - Part 2 |
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Computational Techniques |
Lecture 17 - Regression and Interpolation - Part 3 |
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Computational Techniques |
Lecture 18 - Regression and Interpolation - Part 4 |
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Computational Techniques |
Lecture 19 - Regression and Interpolation - Part 5 |
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Computational Techniques |
Lecture 20 - Differentiation and Integration - Part 1 |
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Computational Techniques |
Lecture 21 - Differentiation and Integration - Part 2 |
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Computational Techniques |
Lecture 22 - Differentiation and Integration - Part 3 |
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Computational Techniques |
Lecture 23 - Differentiation and Integration - Part 4 |
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Computational Techniques |
Lecture 24 - Differentiation and Integration - Part 5 |
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Computational Techniques |
Lecture 25 - Ordinary Differential Equations (initial value problems) - Part 1 |
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Computational Techniques |
Lecture 26 - Ordinary Differential Equations (initial value problems) - Part 2 |
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Computational Techniques |
Lecture 27 - Ordinary Differential Equations (initial value problems) - Part 3 |
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Computational Techniques |
Lecture 28 - Ordinary Differential Equations (initial value problems) - Part 4 |
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Computational Techniques |
Lecture 29 - Ordinary Differential Equations (initial value problems) - Part 5 |
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Computational Techniques |
Lecture 30 - Ordinary Differential Equations (initial value problems) - Part 6 |
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Computational Techniques |
Lecture 31 - Ordinary Differential Equations (initial value problems) - Part 7 |
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Computational Techniques |
Lecture 32 - Ordinary Differential Equations (initial value problems) - Part 8 |
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Computational Techniques |
Lecture 33 - Ordinary Differential Equations (initial value problems) - Part 9 |
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Computational Techniques |
Lecture 34 - Ordinary Differential Equations (boundary value problems) - Part 1 |
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Computational Techniques |
Lecture 35 - Ordinary Differential Equations (boundary value problems) - Part 2 |
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Computational Techniques |
Lecture 36 - Ordinary Differential Equations (boundary value problems) - Part 3 |
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Computational Techniques |
Lecture 37 - Partial Differential Equations - Part 1 |
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Computational Techniques |
Lecture 38 - Partial Differential Equations - Part 2 |
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Computational Techniques |
Lecture 39 - Partial Differential Equations - Part 3 |
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Computational Techniques |
Lecture 40 - Partial Differential Equations - Part 4 |
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Particle Characterization (PG) |
Lecture 1 - Introduction: Why study particle characterization? |
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Particle Characterization (PG) |
Lecture 2 - Introduction: Classification of particle characteristics |
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Particle Characterization (PG) |
Lecture 3 - Morphological Characterization: Shape analysis methods |
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Particle Characterization (PG) |
Lecture 4 - Morphological Characterization: Techniques of shape assessment |
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Particle Characterization (PG) |
Lecture 5 - Morphological Characterization: Decision rules |
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Particle Characterization (PG) |
Lecture 6 - Morphological Characterization: Static vs dynamic methods of size analysis |
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Particle Characterization (PG) |
Lecture 7 - Morphological Characterization: Static methods of size analysis |
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Particle Characterization (PG) |
Lecture 8 - Morphological Characterization: Light scattering from spherical particles |
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Particle Characterization (PG) |
Lecture 9 - Morphological Characterization: Particle counters |
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Particle Characterization (PG) |
Lecture 10 - Morphological Characterization: Particle size distributions |
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Particle Characterization (PG) |
Lecture 11 - Morphological Characterization: Acoustic Attenuation Spectroscopy |
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Particle Characterization (PG) |
Lecture 12 - Morphological Characterization: Nano-particle size analysis |
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Particle Characterization (PG) |
Lecture 13 - Structural Characterization |
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Particle Characterization (PG) |
Lecture 14 - Interfacial Characterization |
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Particle Characterization (PG) |
Lecture 15 - Surface Adhesion: Forces |
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Particle Characterization (PG) |
Lecture 16 - Surface Adhesion: Electrostatic & Surface-Tension Forces |
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Particle Characterization (PG) |
Lecture 17 - Surface Adhesion: Adhesion Force Measurement |
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Particle Characterization (PG) |
Lecture 18 - Particle Removal: Methods |
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Particle Characterization (PG) |
Lecture 19 - Particle Removal: Wet Cleaning |
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Particle Characterization (PG) |
Lecture 20 - Particle Cohesion: Forces |
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Particle Characterization (PG) |
Lecture 21 - Particle Cohesion: Flowability Implications |
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Particle Characterization (PG) |
Lecture 22 - Transport Properties: Diffusion & Electrostatic Field Effects |
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Particle Characterization (PG) |
Lecture 23 - Transport Properties: Drag & Inertia |
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Particle Characterization (PG) |
Lecture 24 - Transport Properties: Deposition Fluxes & Rates |
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Particle Characterization (PG) |
Lecture 25 - Transport Properties: Illustrative Application |
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Particle Characterization (PG) |
Lecture 26 - Chemical & Compositional Characterization: Reactivity |
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Particle Characterization (PG) |
Lecture 27 - Chemical & Compositional Characterization: Analytical Methods |
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Particle Characterization (PG) |
Lecture 28 - Chemical & Compositional Characterization: XRD & AFM |
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Particle Characterization (PG) |
Lecture 29 - Nano-particle Characterization: Bottom-Up Synthesis Methods |
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Particle Characterization (PG) |
Lecture 30 - Nano-particle Characterization: Top-Down Synthesis Methods |
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Particle Characterization (PG) |
Lecture 31 - Nano-particle Characterization: Dispersion |
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Particle Characterization (PG) |
Lecture 32 - Nano-particle Characterization: Properties & Techniques |
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Particle Characterization (PG) |
Lecture 33 - Practical Relevance of Particle Characterization: Nano-Fluids |
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Particle Characterization (PG) |
Lecture 34 - Practical Relevance of Particle Characterization: Filtration |
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Particle Characterization (PG) |
Lecture 35 - Practical Relevance of Particle Characterization: Cleanrooms |
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Particle Characterization (PG) |
Lecture 36 - Practical Relevance of Particle Characterization: High-Technology Manufacturing |
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Particle Characterization (PG) |
Lecture 37 - Practical Relevance of Particle Characterization: Explosivity |
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Particle Characterization (PG) |
Lecture 38 - Practical Relevance of Particle Characterization: Environment & Human Health |
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Particle Characterization (PG) |
Lecture 39 - Practical Relevance of Particle Characterization: Other Applications |
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Particle Characterization (PG) |
Lecture 40 - Summary |
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Statistics for Experimentalists |
Lecture 1 - Introduction |
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Statistics for Experimentalists |
Lecture 2 - Random Variables |
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Statistics for Experimentalists |
Lecture 3 - Discrete Probability Distributions |
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Statistics for Experimentalists |
Lecture 4 - Example Set - I |
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Statistics for Experimentalists |
Lecture 5 - Continuous probability distributions |
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Statistics for Experimentalists |
Lecture 6 - Normal probability distribution |
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Statistics for Experimentalists |
Lecture 7 - Exploratory Data Analysis - Part A |
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Statistics for Experimentalists |
Lecture 8 - Exploratory Data Analysis - Part B |
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Statistics for Experimentalists |
Lecture 9 - Example Set - II |
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Statistics for Experimentalists |
Lecture 10 - Example Set - III |
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Statistics for Experimentalists |
Lecture 11 - Random samples: Sampling distribution of the mean (Part A) |
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Statistics for Experimentalists |
Lecture 12 - Random samples: Sampling distribution of the mean (Part B) |
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Statistics for Experimentalists |
Lecture 13 - Point Estimation |
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Statistics for Experimentalists |
Lecture 14 - Sampling distributions and the Central Limit Theorem |
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Statistics for Experimentalists |
Lecture 15 - Example Set - IV Part A |
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Statistics for Experimentalists |
Lecture 16 - Estimation of Population Parameters Using Moments |
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Statistics for Experimentalists |
Lecture 17 - Confidence Intervals (Part A) |
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Statistics for Experimentalists |
Lecture 18 - Confidence Intervals (Part B) |
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Statistics for Experimentalists |
Lecture 19 - The T-distribution |
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Statistics for Experimentalists |
Lecture 20 - Chi-square distribution |
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Statistics for Experimentalists |
Lecture 21 - F-Distribution |
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Statistics for Experimentalists |
Lecture 22 - Example Set - V |
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Statistics for Experimentalists |
Lecture 23 - Hypothesis Testing - Part A |
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Statistics for Experimentalists |
Lecture 24 - Hypothesis Testing - Part B |
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Statistics for Experimentalists |
Lecture 25 - Hypothesis Testing - Part C |
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Statistics for Experimentalists |
Lecture 26 - Analysis of Experiments involving Single Factor - Part A |
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Statistics for Experimentalists |
Lecture 27 - Analysis of Experiments involving Single Factor - Part B |
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Statistics for Experimentalists |
Lecture 28 - Blocking and Randomization |
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Statistics for Experimentalists |
Lecture 29 - Example Set - VI - Part A |
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Statistics for Experimentalists |
Lecture 30 - Example Set - VI - Part B |
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Statistics for Experimentalists |
Lecture 31 - Factorial Design of Experiments - Part A |
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Statistics for Experimentalists |
Lecture 32 - Factorial Design of Experiments - Part B: 22 Factorial Design |
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Statistics for Experimentalists |
Lecture 33 - Fractional Factorial Design - Part A |
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Statistics for Experimentalists |
Lecture 34 - Fractional Factorial Design - Part B |
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Statistics for Experimentalists |
Lecture 35 - Factorial Design of Experiments: Example Set (Part A) |
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Statistics for Experimentalists |
Lecture 36 - Factorial Design of Experiments: Example Set (Part B) |
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Statistics for Experimentalists |
Lecture 37 - Factorial Design of Experiments: Example Set (Part C) |
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Statistics for Experimentalists |
Lecture 38 - Regression Analysis: Part A |
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Statistics for Experimentalists |
Lecture 39 - Regression Analysis: Part B |
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Statistics for Experimentalists |
Lecture 40 - Hypothesis Testing in Linear Regression |
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Statistics for Experimentalists |
Lecture 41 - Discussion on Regression Output |
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Statistics for Experimentalists |
Lecture 42 - Regression Analysis: Example Set 8 |
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Statistics for Experimentalists |
Lecture 43 - Regression Analysis: Example Set 8 (Continued...) |
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Statistics for Experimentalists |
Lecture 44 - Regression Analysis: Example Set 8 (Continued...) |
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Statistics for Experimentalists |
Lecture 45 - Orthogonal Model Fitting Concepts - Part A |
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Statistics for Experimentalists |
Lecture 46 - Orthogonal Model Fitting Concepts - Part B |
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Statistics for Experimentalists |
Lecture 47 - Experimental Design Strategies - A |
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Statistics for Experimentalists |
Lecture 48 - Experimental Design Strategies - B |
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Statistics for Experimentalists |
Lecture 49 - Experimental Design Strategies - C |
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Statistics for Experimentalists |
Lecture 50 - Response Surface Methodology - A |
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Statistics for Experimentalists |
Lecture 51 - Response Surface Methodology - B |
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Statistics for Experimentalists |
Lecture 52 - Optimal Designs - Part A |
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Statistics for Experimentalists |
Lecture 53 - Optimal Designs - Part B |
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Statistics for Experimentalists |
Lecture 54 - Statistics for Experimentalists - Summary Part A |
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Statistics for Experimentalists |
Lecture 55 - Statistics for Experimentalists - Summary Part B |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 1 - Introduction and overview of the course: Multiphase flows |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 2 - Stratified flow in a micro channel: Velocity profiles |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 3 - Stratified flow in a micro channel: Effects of physical parameters |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 4 - Flow regimes in microchannels: Modeling and Experiments |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 5 - Scaling Analysis: Introduction |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 6 - Scaling Analysis: Worked Examples |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 7 - Interfacial tension and its role in Multiphase flows |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 8 - Eulerian and Lagrangian approaches |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 9 - Reynolds Transport Theorem and the Equation of Continuity |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 10 - Derivation of Navier-Stokes equation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 11 - Vector operations in general orthogonal coordinates: Grad., Div., Lapacian |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 12 - Normal and shear stresses on arbitrary surfaces: Force balance |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 13 - Normal and shear stresses on arbitrary surfaces: Stress Tensor formulation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 14 - Stresses on deforming surfaces: Introduction to Perturbation Theory |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 15 - Pulsatile flow: Analytical solution |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 16 - Pulsatile flow: Analytical solution and perturbation solution for Rw 1 |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 17 - Pulsatile flow: Perturbation solution for Rw 1 |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 18 - Viscous heating: Apparent viscosity in a viscometer |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 19 - Domain perturbation methods: Flow between wavy walls |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 20 - Flow between wavy walls: Velocity profile |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 21 - Introduction to stability of dynamical systems: ODEs |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 22 - Stability of distributed systems (PDEs): reaction diffusion example |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 23 - Stability of a reaction-diffusion system (Continued...) |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 24 - Rayleigh-Benard convection: Physics and governing equations |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 25 - Rayleigh-Benard convection: Linear stability analysis - Part 1 |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 26 - Rayleigh-Benard convection: Linear stability analysis - Part 2 |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 27 - Rayleigh-Benard convection: Linear stability analysis - Part 3 |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 28 - Rayleigh Benard convection: Discussion of results |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 29 - Rayleigh-Taylor ‘heavy over light’ instability |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 30 - Rayleigh-Taylor instability (Continued...) |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 31 - Capillary jet instability: Problem formulation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 32 - Capillary jet instability: Linear stability analysis |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 33 - Capillary jet instability: Rayleigh’s Work Principle |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 34 - Tutorial Session: Solution of Assignment 4 on linear stability |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 35 - Turing patterns: Instability in reaction-diffusion systems |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 36 - Turing patterns: Results |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 37 - Marangoni convection: Generalised tangential and normal stress boundary conditions |
Link |
Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 38 - Marangoni convection: Stability analysis |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 39 - Flow in a circular curved channel: Governing equations and scaling |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 40 - Flow in a circular curved channel: Solution by regular perturbation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 41 - Stability of flow through curved channels: Problem formulation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 42 - Stability of flow through curved channels: Numerical calculation |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 43 - Viscous Fingering: Darcy’s law |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 44 - Viscous Fingering: Stability analysis |
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Multiphase flows:Analytical solutions and Stability Analysis |
Lecture 45 - Shallow Cavity flows |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 1 - Introduction - Lecture 1.1 A |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 2 - Introduction - Lecture 1.1 B |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 3 - Introduction - Lecture 1.2 A |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 4 - Introduction - Lecture 1.2 B |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 5 - Basic Definitions and concepts - Lecture 2.1 (Basic Definitions and concepts - Part I) |
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NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 6 - Basic Definitions and concepts - Lecture 2.2 (Basic Definitions and concepts - Part II) |
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NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 7 - Basic Definitions and concepts - Lecture 2.3 (Basic Definitions and concepts - Part III) |
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NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 8 - A review of Fourier transforms - Lecture 3.1 (Continuous time Fourier series) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 9 - A review of Fourier transforms - Lecture 3.2 (Continuous time Fourier transform) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 10 - A review of Fourier transforms - Lecture 3.3 (Discrete time Fourier series) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 11 - A review of Fourier transforms - Lecture 3.4 (Discrete time Fourier transform) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 12 - A review of Fourier transforms - Lecture 3.5 (Properties of Fourier transforms) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 13 - A review of Fourier transforms - Lecture 3.6 (Discrete Fourier transform) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 14 - A review of Fourier transforms - MATLAB demo of Fourier transform and periodogram |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 15 - Duration and Bandwidth - Duration and Bandwidth |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 16 - Duration and Bandwidth - Bandwidth equation and Instantaneous frequency |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 17 - Duration and Bandwidth - Instantaneous frequency and analytic signals |
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NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 18 - Duration and Bandwidth - Duration-Bandwidth principle |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 19 - Duration and Bandwidth - Requirements of time-frequency anlysis techniques |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 20 - Duration and Bandwidth - Requirements of time-frequency analysis and techniques |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 21 - Short-time Fourier transform - Short-time Fourier transform |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 22 - Short-time Fourier transform - Auxillary (MATLAB demonstration) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 23 - Short-time Fourier transform - Properties of STFT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 24 - Practical aspects of STFT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 25 - Closing Remarks |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 26 - Wigner-Ville Distributions |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 27 - Properties of WVD |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 28 - Properties of WVD 2 |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 29 - Discrete WVD |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 30 - Pseudo and Smoothed WVD |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 31 - Cohens class and smoothed WVD |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 32 - Cohens class and smoothed WVD |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 33 - Cohens class and Ambiguity functions |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 34 - Affine class and closing remarks |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 35 - Continuous Wavelet Transform |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 36 - Continuous Wavelet Transforms |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 37 - Scale to Frequency |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 38 - Computational aspects of CWT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 39 - Scalogram and MATLAB demonstration |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 40 - Scalogram and MATLAB demonstration |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 41 - Scaling function |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 42 - Scaling Function |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 43 - Wavelets |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 44 - Wavelets |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 45 - Applications of CWT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 46 - Applications of CWT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 47 - Discrete Wavelet Transform |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 48 - Discrete Wavelet Transform. |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 49 - Orthogonal scaling function bases and MRA |
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NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 50 - Orthogonal scaling function bases and MRA. |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 51 - Wavelet Filters and Fast DWT Algorithm |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 52 - Wavelet Filters and Fast DWT Algorithm (Continued...) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 53 - Wavelet Filters and Fast DWT Algorithm (Continued...) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 54 - Wavelets for DWT |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 55 - Wavelets for DWT (Continued...) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 56 - Wavelets for DWT (Continued...) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 57 - DWT computation |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 58 - DWT computation (Continued...) |
Link |
NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms |
Lecture 59 - DWT computation (Continued...) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 1 - Introduction |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 2 - CVD Reactor and Process Design Fundamentals |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 3 - Overview of CVD Process Fundamentals |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 4 - Basics of Chemical Equilibrium Calculations and Flow Dynamics |
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Chemical Engineering Principles of CVD Processes |
Lecture 5 - Introduction to CVD Films |
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Chemical Engineering Principles of CVD Processes |
Lecture 6 - Film Structure and Properties |
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Chemical Engineering Principles of CVD Processes |
Lecture 7 - Pressure Effects on CVD Processes |
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Chemical Engineering Principles of CVD Processes |
Lecture 8 - CVD of Metals |
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Chemical Engineering Principles of CVD Processes |
Lecture 9 - CVD of Coatings |
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Chemical Engineering Principles of CVD Processes |
Lecture 10 - CVD Film Property Measurements |
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Chemical Engineering Principles of CVD Processes |
Lecture 11 - CVD Film Property Measurements: Qualitative and Quantitative |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 12 - CVD in Tungsten Filament Lamps |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 13 - CVD in Tungsten Filament Lamps: Design Aspects |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 14 - CVD in Hot Corrosion |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 15 - CVD Transport Phenomena: Conservation Equations |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 16 - CVD Transport Phenomena: Constitutive Laws |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 17 - CVD Transport Phenomena: Mass Transfer Mechanisms |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 18 - CVD Transport Phenomena: Mass Transfer Analogy Condition (MTAC) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 19 - CVD Transport Phenomena: Effect of Homogeneous Reactions on MTAC |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 20 - CVD Applications: Hot Filament CVD (HFCVD) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 21 - CVD Applications: Aerosol CVD (ACVD) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 22 - CVD Applications: CVD of Silicon |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 23 - CVD Applications: CVD in Free-Molecular Flow Regime (FMFR) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 24 - CVD Applications: CVD of nano-Structured Films |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 25 - CVD Overview |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 26 - Review of CVD Basics: Part-I (PDF) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 27 - Review of CVD Basics: Part-II (PDF) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 28 - CVD Question Bank (PDF) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 29 - Basics of Nano-Structured Material Synthesis: Part-I |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 30 - Basics of Nano-Structured Material Synthesis: Part-II |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 31 - Undesirable CVD: Bulb-Blackening (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 32 - Undesirable CVD: Moolten Salt Deposition in Combustion Systems (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 33 - Undesirable CVD: Hot Corrosion (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 34 - Multi-component Transport Fundamentals: Assumptions and Control Volumes (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 35 - Multi-component Transport Fundamentals: Mass Conservation Equations (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 36 - Multi-component Transport Fundamentals: Momentum and Energy Conservation (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 37 - Multi-component Transport Fundamentals: Entropy conservation (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 38 - Multi-component Transport Fundamentals: Constitutive Laws for Mass and Momentum (Adobe Presenter) |
Link |
Chemical Engineering Principles of CVD Processes |
Lecture 39 - Multi-component Transport Fundamentals: Constitutive Laws for Energy and Entropy (Adobe Presenter) |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 1 - Motivation and Introduction - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 2 - Motivation and Introduction - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 3 - What is Chemical Engineering - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 4 - What is Chemical Engineering - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 5 - What is Chemical Reaction Engineering - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 6 - What is Chemical Reaction Engineering - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 7 - Homogeneous and Heterogeneous Reactions - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 8 - Homogeneous and Heterogeneous Reactions - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 9 - Basics of Kinetics and Contacting |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 10 - Design of Batch reactors - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 11 - Design of Batch reactors - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 12 - Basics of Plug Flow Reactor - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 13 - Basics of Plug Flow Reactor - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 14 - Design of Plug Flow Reactors - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 15 - Design of Plug Flow Reactors - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 16 - Basics of Mixed Flow Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 17 - Design of Mixed Flow Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 18 - Basics of Kinetics |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 19 - Kinetics of Heterogeneous reactions - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 20 - Kinetics of Heterogeneous reactions - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 21 - Kinetics of Heterogeneous reactions - Part III |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 22 - Kinetics of Homogeneous reactions |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 23 - Reaction rate for Homogeneous reactions |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 24 - Gas Phase Homogeneous reactions |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 25 - (Continued...) And later Reactor Design of PFR |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 26 - Reactor Design for MFR and Combination of reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 27 - PFR and MFR in series. |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 28 - Unsteady state MFR and PFR |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 29 - Recycle Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 30 - Recycle Reactors (Autocatalytic reactions) - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 31 - Recycle Reactors (Autocatalytic reactions) - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 32 - Multiple Reactions - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 33 - Multiple Reactions - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 34 - Multiple Reactions - Part III |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 35 - Multiple Reactions - Part IV |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 36 - Multiple Reactions - Part V |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 37 - Multiple Reactions - Part VI |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 38 - Non-Isothermal Reactors - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 39 - Non-Isothermal Reactors - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 40 - Non-Isothermal Reactors (Graphical Design) |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 41 - Non-Isothermal Reactors contd. & Adiabatic Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 42 - Non-Isothermal Reactors (Graphical Design) (Continued...) |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 43 - Non-Isothermal Batch Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 44 - Non-isothermal Plug Flow Reactors - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 45 - Non-isothermal Plug Flow Reactors - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 46 - Adiabatic Plug Flow Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 47 - Non-isothermal Mixed Flow Reactors |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 48 - Non-isothermal Mixed Flow Reactors (Continued...) (Multiple steady states) - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 49 - Non-isothermal Mixed Flow Reactors (Continued...) (Multiple steady states) - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 50 - Non-Ideal Flow and Residence Time Distributions (RTD) basics - Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 51 - Non-Ideal Flow and Residence Time Distributions (RTD) basics - Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 52 - RTD for various reactors (Continued...) Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 53 - RTD for various reactors (Continued...) Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 54 - Diagnosing the ills of equipments and Various RTD Models |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 55 - Dispersion Model |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 56 - Dispersion with reaction Model and Tanks in Series Model |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 57 - Multi-parameter model (MFR with dead space and bypass) |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 58 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part I |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 59 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part II |
Link |
Chemical Reaction Engineering 1 (Homogeneous Reactors) |
Lecture 60 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part III |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 1 - Introduction to Kinetics (Gas solid non-catalytic reaction) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 2 - Intro to Kinetics (Continued...) for catalytic reactions in different reactors |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 3 - Heterogeneous rate of reactions and different types of kinetic models for non-catalytic reactions |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 4 - Basics of Kinetics of type A & B reactions (Shrinking core model & Porous particle homogeneous model) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 5 - Shrinking Core Model (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 6 - Shrinking Core Model (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 7 - (Continued...) & Proof of Pseudo steady state assumption |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 8 - Shrinking core model (Continued...) for type D reactions |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 9 - Shrinking core model (Continued...) for type D reactions (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 10 - Reactors, Homogeneous reaction model, Design of non-catalytic gas solid reactors |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 11 - Design of non-catalytic gas solid reactors (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 12 - Design of non-catalytic gas solid reactors (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 13 - Design equation for MF of solids, uniform gas composition, const. single particle size, Shrinking core model. |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 14 - Design equation for MF of solids, mixture of particles for different sizes but unchanging size, uniform gas composition, SCM |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 15 - Design equation for MF of solids with elutriation, mixture of particles of different size, uniform gas composition, SCM |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 16 - General Performance equation for non-catalytic gas solid reactions |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 17 - Catalytic reactions (LHHW Kinetic model) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 18 - LHHW Kinetic model (Continued...) - Part I |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 19 - LHHW Kinetic model (Continued...) - Part II |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 20 - Industrially important catalytic reaction models |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 21 - Inter and Intraphase effectiveness fator |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 22 - Interface effectiveness factor & Generalized nonisothermal effectiveness factor for external mass transfer stepÂ… |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 23 - Generalized nonisothermal effectiveness factor for external mass transfer step (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 24 - Mass transfer correlations for various reactors |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 25 - Isothermal intraphase effectiveness factor - Part I |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 26 - Isothermal intraphase effectiveness factor - Part II |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 27 - Non-isothermal intraphase effectiveness factor |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 28 - Inter and Intraphase effectiveness factor (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 29 - Inter and Intraphase Mass transfer |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 30 - Packed (fixed) bed catalytic reactor design |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 31 - Graphical design of Fixed bed reactors |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 32 - Packed Bed Design (Continued...) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 33 - Design equations for Packed bed reactor design |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 34 - Conservative Equations for Packed bed Reactor design |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 35 - Problem solving session |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 36 - Fluidized Bed Reactor Design - Part I |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 37 - Fluidized Bed Reactor Design - Part II |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 38 - Fluidized Bed Reactor Design - Part III |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 39 - Fluidized Bed Reactor Design - Part IV |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 40 - Continued... (Fluidized bed reactor Models) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 41 - Continued... (Davidson Harrison model and Kunii Levenspiel model) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 42 - Continued... (Kunii Levenspiel Model) |
Link |
Chemical Reaction Engineering 2 (Heterogeneous Reactors) |
Lecture 43 - Slurry Reactor Design |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 1 - Course Introduction |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 2 - Basics of Programming using MATLAB |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 3 - Array Operations in MATLAB |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 4 - Loops and Execution Control |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 5 - Tutorial: Using Arrays |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 6 - MATLAB Files -- Scripts and Functions |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 7 - Plotting and Output |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 8 - How to submit MATLAB Assignment |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 9 - Errors in Numerical Computation |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 10 - Truncation Errors and Taylors Series |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 11 - Round-Off Errors; and Iterative Methods |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 12 - Step-wise Methods and Error Propagation |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 13 - How to get MATLAB Online access (for all enrolled students of this course) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 14 - Differentiation in Single Variable |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 15 - Higher Order Differentiation Formulae |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 16 - Partial Differentials (Bonus) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 17 - Numerical Integration |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 18 - Multiple Applications of Integration Formulae |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 19 - In-Build MATLAB Integration Functions |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 20 - Basics of Linear Algebra |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 21 - Gauss Elimination and Back-Substitution |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 22 - LU Decomposition and Partial Pivoting |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 23 - Gauss Siedel Method |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 24 - (Tutorial) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 25 - Tri-Diagonal Matrix Algorithm |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 26 - Nonlinear Equations in Single Variable |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 27 - Using MATLAB command fzero |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 28 - Fixed Point Iteration in Single Variable |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 29 - Newton-Raphson (single variable) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 30 - Using MATLAB command fsolve (multi-variable) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 31 - Newton-Raphson (multi Variable) |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 32 - Introduction |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 33 - Linear Least Squares Regression |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 34 - Nonlinear and Functional Regression |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 35 - Interpolation Functions in MATLAB |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 36 - Introduction and Euler\'s Method |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 37 - Runge-Kutta (RK-2) method |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 38 - MATLAB ode45 algorithm |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 39 - Higher order Runge-Kutta Methods |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 40 - Error Analysis |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 41 - Multi-Variable ODE |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 42 - Stiff Systems & Solution using ode15s |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 43 - Method of Lines for transient PDEs |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 44 - A Final Example |
Link |
NOC:MATLAB Programming for Numerical Computation |
Lecture 45 - Tutorial: How to do linear and nonlinear regression |
Link |
NOC:Computational Fluid Dynamics |
Lecture 1 - Motivation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 2 - Flow in a rectangular duct: Problem formulation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 3 - Flow in a rectangular duct: Discretiztion of flow domain |
Link |
NOC:Computational Fluid Dynamics |
Lecture 4 - Tutorial 1: Converting PDE to algebraic equation using FD approximation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 5 - Tutorial 1 (Continued...) Solution for algebraic equations using Gauss- Seidel Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 6 - Flow in a triangular duct: Problem formulation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 7 - Flow in a triangular duct: Discretiztion of flow domain |
Link |
NOC:Computational Fluid Dynamics |
Lecture 8 - Tutorial 2: Converting PDE to algebraic equation using Finite Volume method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 9 - Tutorial 2 (Continued...) Description of FV method and solution using G-S Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 10 - Effect of grid spacing & upcoming course outline |
Link |
NOC:Computational Fluid Dynamics |
Lecture 11 - Mass conservation equations |
Link |
NOC:Computational Fluid Dynamics |
Lecture 12 - Momentum conservation equations |
Link |
NOC:Computational Fluid Dynamics |
Lecture 13 - Forces acting on control volume |
Link |
NOC:Computational Fluid Dynamics |
Lecture 14 - Kinematics of deformation in fluid flow |
Link |
NOC:Computational Fluid Dynamics |
Lecture 15 - Equations governing fluid flow in incompressible fluid |
Link |
NOC:Computational Fluid Dynamics |
Lecture 16 - Navier-Stokes equation for simple cases of flow |
Link |
NOC:Computational Fluid Dynamics |
Lecture 17 - Energy conservation equations |
Link |
NOC:Computational Fluid Dynamics |
Lecture 18 - Practical cases of fluid flow with heat transfer in CFD point of view |
Link |
NOC:Computational Fluid Dynamics |
Lecture 19 - Practical cases of fluid flow with mass transfer in CFD point of view |
Link |
NOC:Computational Fluid Dynamics |
Lecture 20 - Equations governing fluid flow with chemical reactions |
Link |
NOC:Computational Fluid Dynamics |
Lecture 21 - Concept of wellposedness of mathematical problems |
Link |
NOC:Computational Fluid Dynamics |
Lecture 22 - Introduction to finite difference methods |
Link |
NOC:Computational Fluid Dynamics |
Lecture 23 - Finite difference approximation on an uniform mesh |
Link |
NOC:Computational Fluid Dynamics |
Lecture 24 - Higher order and mixed derivatives |
Link |
NOC:Computational Fluid Dynamics |
Lecture 25 - Solution of Poisson equation in rectangular duct-Turorial |
Link |
NOC:Computational Fluid Dynamics |
Lecture 26 - Discretization of time domain |
Link |
NOC:Computational Fluid Dynamics |
Lecture 27 - FD approx. on a non-uniform mesh and need of analysis of obtained discretization |
Link |
NOC:Computational Fluid Dynamics |
Lecture 28 - Need for the analysis of discretized equation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 29 - Properties of Numerical Schemes: Accuracy, Conservation property, Boundedness, Consistency, Stability and Convergence |
Link |
NOC:Computational Fluid Dynamics |
Lecture 30 - Properties of Numerical Schemes: Stability analysis |
Link |
NOC:Computational Fluid Dynamics |
Lecture 31 - Tutorial on Stability Analysis |
Link |
NOC:Computational Fluid Dynamics |
Lecture 32 - Analysis of Generic 1-d scalar transport equation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 33 - Introduction to the solution of coupled N-S equations |
Link |
NOC:Computational Fluid Dynamics |
Lecture 34 - N-S equation in compressible flow- Mac Cormack Scheme |
Link |
NOC:Computational Fluid Dynamics |
Lecture 35 - Stability limits of Mac-Cormack Scheme and the intro to Beam-Warming Scheme |
Link |
NOC:Computational Fluid Dynamics |
Lecture 36 - Implicit Beam-Warming Scheme |
Link |
NOC:Computational Fluid Dynamics |
Lecture 37 - Compressible flow to Incompressible flow |
Link |
NOC:Computational Fluid Dynamics |
Lecture 38 - Solution of coupled equations: Incompressible flow |
Link |
NOC:Computational Fluid Dynamics |
Lecture 39 - Artificial compressiblity method, Stream function-vorticity method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 40 - Pressure equation method, Staggered grid system |
Link |
NOC:Computational Fluid Dynamics |
Lecture 41 - Pressure Correction Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 42 - Tutorial on Pressure Correction Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 43 - Tutorial on Pressure Correction Method (Continued...) |
Link |
NOC:Computational Fluid Dynamics |
Lecture 44 - Introduction to the basic numerical methods |
Link |
NOC:Computational Fluid Dynamics |
Lecture 45 - Direct Methods: solution of the system of algebraic equations |
Link |
NOC:Computational Fluid Dynamics |
Lecture 46 - Tri-diagonal Matrix Algorithm: Derivation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 47 - TDMA and other iterative methods |
Link |
NOC:Computational Fluid Dynamics |
Lecture 48 - Recap of basic iterative methods. |
Link |
NOC:Computational Fluid Dynamics |
Lecture 49 - Convergence analysis of basic iterative methods |
Link |
NOC:Computational Fluid Dynamics |
Lecture 50 - Successive Over Relaxation (SOR) method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 51 - Alternating Direction Implicit (ADI) method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 52 - Strongly Implicit Procedure (ILU) method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 53 - Multigrid method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 54 - Body Fitted Grid Approach |
Link |
NOC:Computational Fluid Dynamics |
Lecture 55 - Formulation Of Finite Volume Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 56 - Methods For Unstructured Grid Generation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 57 - Triangulation: The Advancing Front Method |
Link |
NOC:Computational Fluid Dynamics |
Lecture 58 - The Advancing Front Method continuation |
Link |
NOC:Computational Fluid Dynamics |
Lecture 59 - Time and length scale of turbulance |
Link |
NOC:Computational Fluid Dynamics |
Lecture 60 - The turbulent closure problem |
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NOC:Computational Fluid Dynamics |
Lecture 61 - The generic formulation for turbulence |
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NOC:Computational Fluid Dynamics |
Lecture 62 - More generic formulation and summary |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 1 - Motivation |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 2 - Probability and statistics: Review - Part 1 |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 3 - Probability and Statistics: Review - Part 2 |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 4 - R Tutorial 1 |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 5 - Statistics for Hypothesis Testing - Part 1 |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 6 - Statistics for Hypothesis Testing - Part 2 |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 7 - Statistics for sample mean |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 8 - Statistics for Variance and Proportion |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 9 - Type I and Type II errors |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 10 - p value |
Link |
NOC:Introduction to Statistical Hypothesis Testing |
Lecture 11 - Hypothesis testing of means |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 12 - Hypothesis testing of variance and proportions |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 13 - Confidence interval construction |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 14 - Hypothesis testing using confidence interval |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 15 - Hypothesis testing of correlation |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 16 - Statistic for linear regression |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 17 - Hypothesis testing in linear regression |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 18 - Power of hypothesis test |
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NOC:Introduction to Statistical Hypothesis Testing |
Lecture 19 - Factors affecting hypothesis test |
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NOC:Applied Time-Series Analysis |
Lecture 1 - Lecture 1 - Part 1 - Motivation and Overview 1 |
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NOC:Applied Time-Series Analysis |
Lecture 2 - Lecture 1 - Part 2 - Motivation and Overview 2 |
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NOC:Applied Time-Series Analysis |
Lecture 3 - Lecture 2 - Part 1 - Motivation and Overview 3 |
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NOC:Applied Time-Series Analysis |
Lecture 4 - Lecture 2 - Part 2 - Motivation and Overview 4 |
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NOC:Applied Time-Series Analysis |
Lecture 5 - Lecture 3 - Part 1 - Motivation and Overview 5 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 6 - Lecture 3 - Part 2 - Motivation and Overview 6 |
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NOC:Applied Time-Series Analysis |
Lecture 7 - Lecture 4 - Part 1 - Probability and Statistics Review 1A |
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NOC:Applied Time-Series Analysis |
Lecture 8 - Lecture 4 - Part 2 - Probability and Statistics Review 1B |
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NOC:Applied Time-Series Analysis |
Lecture 9 - Lecture 5 - Part 1 - Probability and Statistics Review 1C |
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NOC:Applied Time-Series Analysis |
Lecture 10 - Lecture 5 - Part 2 - Probability and Statistics Review 1D |
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NOC:Applied Time-Series Analysis |
Lecture 11 - Lecture 6 - Part 1 - Probability and Statistics Review 2A |
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NOC:Applied Time-Series Analysis |
Lecture 12 - Lecture 6 - Part 2 - Probability and Statistics Review 2B |
Link |
NOC:Applied Time-Series Analysis |
Lecture 13 - Lecture 6 - Part 3 - Probability and Statistics Review 2C |
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NOC:Applied Time-Series Analysis |
Lecture 14 - Lecture 7 - Part 1 - Probability and Statistics Review 2D |
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NOC:Applied Time-Series Analysis |
Lecture 15 - Lecture 7 - Part 2 - Probability and Statistics Review 2E |
Link |
NOC:Applied Time-Series Analysis |
Lecture 16 - Lecture 7 - Part 3 - Probability and Statistics Review 2F |
Link |
NOC:Applied Time-Series Analysis |
Lecture 17 - Lecture 8 - Part 1 - Probability and Statistics Review 2G (with R Demonstration) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 18 - Lecture 8 - Part 2 - Probability and Statistics Review 2H (with R Demonstration) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 19 - Lecture 9 - Part 1 - Probability and Statistics Review 2I |
Link |
NOC:Applied Time-Series Analysis |
Lecture 20 - Lecture 9 - Part 2 - Probability and Statistics Review 2J |
Link |
NOC:Applied Time-Series Analysis |
Lecture 21 - Lecture 9 - Part 3 - Introduction to Random Processes 1 |
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NOC:Applied Time-Series Analysis |
Lecture 22 - Lecture 10 - Part 1 - Introduction to Random Processes 2 |
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NOC:Applied Time-Series Analysis |
Lecture 23 - Lecture 10 - Part 2 - Introduction to Random Processes 3 |
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NOC:Applied Time-Series Analysis |
Lecture 24 - Lecture 11 - Part 1 - Introduction to Random Processes 4 |
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NOC:Applied Time-Series Analysis |
Lecture 25 - Lecture 11 - Part 2 - Introduction to Random Processes 5 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 26 - Lecture 11 - Part 3 - Autocovariance & Autocorrelation Functions 1 |
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NOC:Applied Time-Series Analysis |
Lecture 27 - Lecture 12 - Part 1 - Autocovariance & Autocorrelation Functions 2 |
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NOC:Applied Time-Series Analysis |
Lecture 28 - Lecture 12 - Part 2 - Autocovariance & Autocorrelation Functions 3 |
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NOC:Applied Time-Series Analysis |
Lecture 29 - Lecture 13 - Part 1 - Autocovariance & Autocorrelation Functions 4 |
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NOC:Applied Time-Series Analysis |
Lecture 30 - Lecture 13 - Part 2 - Autocovariance & Autocorrelation Functions 5 |
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NOC:Applied Time-Series Analysis |
Lecture 31 - Lecture 13 - Part 3 - Autocovariance & Autocorrelation Functions 6 |
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NOC:Applied Time-Series Analysis |
Lecture 32 - Lecture 14 - Part 1 - Autocovariance & Autocorrelation Functions 7 |
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NOC:Applied Time-Series Analysis |
Lecture 33 - Lecture 14 - Part 2 - Autocovariance & Autocorrelation Functions 8 |
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NOC:Applied Time-Series Analysis |
Lecture 34 - Lecture 15 - Part 1 - Autocovariance & Autocorrelation Functions 9 |
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NOC:Applied Time-Series Analysis |
Lecture 35 - Lecture 15 - Part 2 - Partial Autocorrelation Functions |
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NOC:Applied Time-Series Analysis |
Lecture 36 - Lecture 16 - Part 1 - Autocorrelation and Partial-autocorrelation Functions (with R Demonstration) |
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NOC:Applied Time-Series Analysis |
Lecture 37 - Lecture 16 - Part 2 - Models for Linear Stationary Processes 1 |
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NOC:Applied Time-Series Analysis |
Lecture 38 - Lecture 17 - Part 1 - Models for Linear Stationary Processes 2 |
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NOC:Applied Time-Series Analysis |
Lecture 39 - Lecture 17 - Part 2 - Models for Linear Stationary Processes 3 |
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NOC:Applied Time-Series Analysis |
Lecture 40 - Lecture 18 - Part 1 - Models for Linear Stationary Processes 4 |
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NOC:Applied Time-Series Analysis |
Lecture 41 - Lecture 18 - Part 2 - Models for Linear Stationary Processes 5 |
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NOC:Applied Time-Series Analysis |
Lecture 42 - Lecture 18 - Part 3 - Models for Linear Stationary Processes 6 |
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NOC:Applied Time-Series Analysis |
Lecture 43 - Lecture 19 - Part 1 - Models for Linear Stationary Processes 7 |
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NOC:Applied Time-Series Analysis |
Lecture 44 - Lecture 19 - Part 2 - Models for Linear Stationary Processes 8 |
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NOC:Applied Time-Series Analysis |
Lecture 45 - Lecture 19 - Part 3 - Models for Linear Stationary Processes 9 |
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NOC:Applied Time-Series Analysis |
Lecture 46 - Lecture 20 - Part 1 - Models for Linear Stationary Processes 10 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 47 - Lecture 20 - Part 2 - Models for Linear Stationary Processes 11 |
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NOC:Applied Time-Series Analysis |
Lecture 48 - Lecture 21 - Part 1 - Models for Linear Stationary Processes 12 |
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NOC:Applied Time-Series Analysis |
Lecture 49 - Lecture 21 - Part 2 - Models for Linear Stationary Processes 13 |
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NOC:Applied Time-Series Analysis |
Lecture 50 - Lecture 22 - Part 1 - Models for Linear Stationary Processes 14 (with R Demonstrations) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 51 - Lecture 22 - Part 2 - Models for Linear Stationary Processes 15 (with R Demonstrations) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 52 - Lecture 22 - Part 3 - Models for Linear Stationary Processes 16 (with R Demonstrations) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 53 - Lecture 23 - Part 1 - Models for Linear Non-stationary Processes 1 |
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NOC:Applied Time-Series Analysis |
Lecture 54 - Lecture 23 - Part 2 - Models for Linear Non-stationary Processes 2 (with R Demonstrations) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 55 - Lecture 24 - Part 1 - Models for Linear Non-stationary Processes 3 (with R Demonstrations) |
Link |
NOC:Applied Time-Series Analysis |
Lecture 56 - Lecture 24 - Part 2 - Models for Linear Non-stationary Processes 4 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 57 - Lecture 25 - Part 1 - Models for Linear Non-stationary Processes 5 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 58 - Lecture 25 - Part 2 - Models for Linear Non-stationary Processes 6 (with R Demonstrations) |
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NOC:Applied Time-Series Analysis |
Lecture 59 - Lecture 26 - Part 1 - Fourier Transforms for Deterministic Signals 1 |
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NOC:Applied Time-Series Analysis |
Lecture 60 - Lecture 26 - Part 2 - Fourier Transforms for Deterministic Signals 2 |
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NOC:Applied Time-Series Analysis |
Lecture 61 - Lecture 27 - Part 1 - Fourier Transforms for Deterministic Signals 3 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 62 - Lecture 27 - Part 2 - Fourier Transforms for Deterministic Signals 4 |
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NOC:Applied Time-Series Analysis |
Lecture 63 - Lecture 28 - Part 1 - Fourier Transforms for Deterministic Signals 5 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 64 - Lecture 28 - Part 2 - Fourier Transforms for Deterministic Signals 6 |
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NOC:Applied Time-Series Analysis |
Lecture 65 - Lecture 29 - Part 1 - Fourier Transforms for Deterministic Signals 7 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 66 - Lecture 29 - Part 2 - Fourier Transforms for Deterministic Signals 8 |
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NOC:Applied Time-Series Analysis |
Lecture 67 - Lecture 30 - Part 1 - Fourier Transforms for Deterministic Signals 9 |
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NOC:Applied Time-Series Analysis |
Lecture 68 - Lecture 30 - Part 2 - DFT and Periodogram 1 |
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NOC:Applied Time-Series Analysis |
Lecture 69 - Lecture 31 - Part 1 - DFT and Periodogram 2 |
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NOC:Applied Time-Series Analysis |
Lecture 70 - Lecture 31 - Part 2 - DFT and Periodogram 3 (with R Demonstrations) |
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NOC:Applied Time-Series Analysis |
Lecture 71 - Lecture 32 - Part 1 - Spectral Representations of Random Processes 1 |
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NOC:Applied Time-Series Analysis |
Lecture 72 - Lecture 32 - Part 2 - Spectral Representations of Random Processes 2 |
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NOC:Applied Time-Series Analysis |
Lecture 73 - Lecture 33 - Part 1 - Spectral Representations of Random Processes 3 |
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NOC:Applied Time-Series Analysis |
Lecture 74 - Lecture 33 - Part 2 - Spectral Representations of Random Processes 4 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 75 - Lecture 33 - Part 3 - Spectral Representations of Random Processes 5 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 76 - Lecture 34 - Part 1 - Spectral Representations of Random Processes 6 |
Link |
NOC:Applied Time-Series Analysis |
Lecture 77 - Lecture 34 - Part 2 - Spectral Representations of Random Processes 7 |
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NOC:Applied Time-Series Analysis |
Lecture 78 - Lecture 35 - Part 1 - Introduction to Estimation Theory 1 |
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NOC:Applied Time-Series Analysis |
Lecture 79 - Lecture 35 - Part 2 - Introduction to Estimation Theory 2 |
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NOC:Applied Time-Series Analysis |
Lecture 80 - Lecture 35 - Part 3 - Introduction to Estimation Theory 3 |
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NOC:Applied Time-Series Analysis |
Lecture 81 - Lecture 36A - Introduction to Estimation Theory -4 |
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NOC:Applied Time-Series Analysis |
Lecture 82 - Lecture 36B - Goodness of Estimators 1 - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 83 - Lecture 37A - Goodness of Estimators 1 - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 84 - Lecture 37B - Goodness of Estimators 1 - 3 |
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NOC:Applied Time-Series Analysis |
Lecture 85 - Lecture 37C - Goodness of Estimators 1 - 4 |
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NOC:Applied Time-Series Analysis |
Lecture 86 - Lecture 38A - Goodness of Estimators 2 - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 87 - Lecture 38B - Goodness of Estimators 2 - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 88 - Lecture 38C - Goodness of Estimators 2 - 3 |
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NOC:Applied Time-Series Analysis |
Lecture 89 - Lecture 39A - Goodness of Estimators 2 - 4 |
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NOC:Applied Time-Series Analysis |
Lecture 90 - Lecture 39B - Goodness of Estimators 2 - 5 (with R demonstrations) |
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NOC:Applied Time-Series Analysis |
Lecture 91 - Lecture 39C - Goodness of Estimators 2 - 6 |
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NOC:Applied Time-Series Analysis |
Lecture 92 - Lecture 40A - Goodness of Estimators 2 - 7 |
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NOC:Applied Time-Series Analysis |
Lecture 93 - Lecture 40B - Goodness of Estimators 2 - 8 |
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NOC:Applied Time-Series Analysis |
Lecture 94 - Lecture 41A - Estimation Methods 1 - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 95 - Lecture 41B - Estimation Methods 1 - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 96 - Lecture 42A - Estimation Methods 1 - 3 |
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NOC:Applied Time-Series Analysis |
Lecture 97 - Lecture 42B - Estimation Methods 1 - 4 |
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NOC:Applied Time-Series Analysis |
Lecture 98 - Lecture 42C - Estimation Methods 1 - 5 |
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NOC:Applied Time-Series Analysis |
Lecture 99 - Lecture 43A - Estimation Methods 1 - 6 (with R demonstrations) |
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NOC:Applied Time-Series Analysis |
Lecture 100 - Lecture 43B - Estimation Methods 1 - 7 (with R demonstrations) |
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NOC:Applied Time-Series Analysis |
Lecture 101 - Lecture 44A - Estimation Methods 1 - 8 |
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NOC:Applied Time-Series Analysis |
Lecture 102 - Lecture 44B - Estimation Methods 1 - 9 |
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NOC:Applied Time-Series Analysis |
Lecture 103 - Lecture 44C - Estimation Methods 2 - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 104 - Lecture 45A - Estimation Methods 2 - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 105 - Lecture 45B - Estimation Methods 2 - 3 |
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NOC:Applied Time-Series Analysis |
Lecture 106 - Lecture 46A - MLE and Bayesian Estimation - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 107 - Lecture 46B - MLE and Bayesian Estimation - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 108 - Lecture 47A - MLE and Bayesian Estimation - 3 |
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NOC:Applied Time-Series Analysis |
Lecture 109 - Lecture 47B - MLE and Bayesian Estimation - 4 |
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NOC:Applied Time-Series Analysis |
Lecture 110 - Lecture 48A - Estimation of Time Domain Statistics - 1 |
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NOC:Applied Time-Series Analysis |
Lecture 111 - Lecture 48B - Estimation of Time Domain Statistics - 2 |
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NOC:Applied Time-Series Analysis |
Lecture 112 - Lecture 49 - Periodogram as PSD Estimator |
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NOC:Rheology of Complex Materials |
Lecture 1 - Flow phenomena in complex materials and Microstructure - 1 |
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NOC:Rheology of Complex Materials |
Lecture 2 - Flow phenomena in complex materials and Microstructure - 2 |
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NOC:Rheology of Complex Materials |
Lecture 3 - Applications of rheology : mechanisms at the molecular and microscopic scales - 1 |
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NOC:Rheology of Complex Materials |
Lecture 4 - Applications of rheology : mechanisms at the molecular and microscopic scales - 2 |
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NOC:Rheology of Complex Materials |
Lecture 5 - Applications of rheology : some example material systems - 1 |
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NOC:Rheology of Complex Materials |
Lecture 6 - Applications of rheology : some example material systems - 2 |
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NOC:Rheology of Complex Materials |
Lecture 7 - Stress and strain rate - 1 |
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NOC:Rheology of Complex Materials |
Lecture 8 - Stress and strain rate - 2 |
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NOC:Rheology of Complex Materials |
Lecture 9 - Velocity gradient and strain rate - 1 |
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NOC:Rheology of Complex Materials |
Lecture 10 - Velocity gradient and strain rate 1 Stress and strain rate - 3 |
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NOC:Rheology of Complex Materials |
Lecture 11 - Kinematics for simple flows - 1 |
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NOC:Rheology of Complex Materials |
Lecture 12 - Kinematics for simple flows - 2 |
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NOC:Rheology of Complex Materials |
Lecture 13 - Introduction to tensors |
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NOC:Rheology of Complex Materials |
Lecture 14 - Rheometric flows |
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NOC:Rheology of Complex Materials |
Lecture 15 - Viscous response - 1 |
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NOC:Rheology of Complex Materials |
Lecture 16 - Viscous response - 2 |
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NOC:Rheology of Complex Materials |
Lecture 17 - Viscoelasticity - Relaxation process |
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NOC:Rheology of Complex Materials |
Lecture 18 - Viscoelasticity - Maxwell model |
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NOC:Rheology of Complex Materials |
Lecture 19 - Linear viscoelasticity - oscillatory shear - 1 |
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NOC:Rheology of Complex Materials |
Lecture 20 - Linear viscoelasticity - oscillatory shear - 2 |
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NOC:Rheology of Complex Materials |
Lecture 21 - Introduction to tensors - 2 |
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NOC:Rheology of Complex Materials |
Lecture 22 - Introduction to tensors - 3 |
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NOC:Rheology of Complex Materials |
Lecture 23 - Rheometers - 1 |
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NOC:Rheology of Complex Materials |
Lecture 24 - Rheometers - 2 |
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NOC:Rheology of Complex Materials |
Lecture 25 - Rheometers - 3 |
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NOC:Rheology of Complex Materials |
Lecture 26 - Rheometers - 4 |
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NOC:Rheology of Complex Materials |
Lecture 27 - Rheometers - 5 |
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NOC:Rheology of Complex Materials |
Lecture 28 - Governing equations for rheology - 1 |
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NOC:Rheology of Complex Materials |
Lecture 29 - Governing equations for rheology - 2 |
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NOC:Rheology of Complex Materials |
Lecture 30 - Relaxation time spectrum - 1 |
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NOC:Rheology of Complex Materials |
Lecture 31 - Relaxation time spectrum - 2 |
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NOC:Rheology of Complex Materials |
Lecture 32 - Linear viscoelasticity: generalized Maxwell model |
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NOC:Rheology of Complex Materials |
Lecture 33 - Time temperature superposition |
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NOC:Rheology of Complex Materials |
Lecture 34 - Linear viscoelasticity: solidlike materials |
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NOC:Rheology of Complex Materials |
Lecture 35 - General linear viscoelasticity |
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NOC:Rheology of Complex Materials |
Lecture 36 - Rotational rheometry |
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NOC:Rheology of Complex Materials |
Lecture 37 - Review of material functions - 1 |
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NOC:Rheology of Complex Materials |
Lecture 38 - Review of material functions - 2 |
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NOC:Rheology of Complex Materials |
Lecture 39 - Survey of material functions for polymers - 1 |
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NOC:Rheology of Complex Materials |
Lecture 40 - Survey of material functions for polymers - 2 |
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NOC:Rheology of Complex Materials |
Lecture 41 - Survey of material functions for polymers - 3 |
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NOC:Rheology of Complex Materials |
Lecture 42 - Survey of material functions for polymers - 4 |
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