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  • Aeronautical Engineering

Aeronautical Engineering

Curriculum

  • 11 Sections
  • 415 Lessons
  • 10 Weeks
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  • Acoustic Instabilities in Aerospace Propulsion
    41
    • 2.1
      Introduction to Thermoacoustic
    • 2.2
      Introduction to Acoustics Conservation Equations
    • 2.3
      Wave Equation and its Solution in Time Domain
    • 2.4
      Harmonic Waves & Acoustic Energy Corollory
    • 2.5
      Standing Waves Part-1
    • 2.6
      Standing Waves Part-2
    • 2.7
      Power Flow and Acoustic Admittance
    • 2.8
      Impedance Tube Technique
    • 2.9
      Admittance and Standing Waves
    • 2.10
      Admittance, Stability and Attenuation
    • 2.11
      Sound Propagation Through Inhomogeneous Media – 1
    • 2.12
      Sound Propagation Through Inhomogeneous Media – 2
    • 2.13
      Sound Propagation Through Inhomogeneous Media – 3
    • 2.14
      Multidimensional Acoustic Fields – 1
    • 2.15
      Multidimensional Acoustic Fields – 2
    • 2.16
      Interaction between Sound and Combustion
    • 2.17
      Reference Books Derivation of Rayleigh Criteria
    • 2.18
      Effect of Heat release on the Acoustic Field
    • 2.19
      Modal Analysis of Thermoacoustic Instability – 1
    • 2.20
      Modal Analysis of Thermoacoustic Instability – 2
    • 2.21
      Active Control of Thermoacoustic Instability
    • 2.22
      Toy model for a Rijke tube in Time Domain
    • 2.23
      Galerkin Technique for Thermoacoustics
    • 2.24
      Evolution Equation for Thermoacoustics
    • 2.25
      Non linear analysis of Thermoacoustic Instability
    • 2.26
      Non-normality, Transient Growth and Triggering Instability – 1
    • 2.27
      Non-normality, Transient Growth and Triggering Instability – 2
    • 2.28
      Non-normality, Transient Growth and Triggering Instability – 3
    • 2.29
      Bifurcations
    • 2.30
      Premixed Flame Acoustic Interaction – 1
    • 2.31
      Premixed Flame Acoustic Interaction – 2
    • 2.32
      Combustion instability due to Equivalence Ratio Fluctuation
    • 2.33
      Role of Hydrodynamic Instabilities – 1
    • 2.34
      Role of Hydrodynamic Instabilities – 2
    • 2.35
      Role of Hydrodynamic Instabilities – 3
    • 2.36
      Active Control of Thermoacoustic Instability
    • 2.37
      Solid Propellant Combustion Instability – 1
    • 2.38
      Solid Propellant Combustion Instability – 2
    • 2.39
      Response of a Diffusion Flame to Acoustic Oscillations -1
    • 2.40
      Response of a Diffusion Flame to Acoustic Oscillations -2
    • 2.41
      Response of a Diffusion Flame to Acoustic Oscillations -3
  • Advanced Control System Design for Aerospace Vehicles
    40
    • 3.1
      Introduction and Motivation for Advanced Control Design
    • 3.2
      Classical Control Overview – I
    • 3.3
      Classical Control Overview – II
    • 3.4
      Classical Control Overview – III
    • 3.5
      Classical Control Overview – IV
    • 3.6
      Basic Principles of Atmospheric Flight Mechanics
    • 3.7
      Overview of Flight Dynamics – I
    • 3.8
      Overview of Flight Dynamics – II
    • 3.9
      Representation of Dynamical Systems – I
    • 3.10
      Representation of Dynamical Systems – II
    • 3.11
      Representation of Dynamical Systems – III
    • 3.12
      Review of Matrix Theory – I
    • 3.13
      Review of Matrix Theory – II
    • 3.14
      Review of Matrix Theory – III
    • 3.15
      Review of Numerical Methods
    • 3.16
      Linearization of Nonlinear Systems
    • 3.17
      First and Second Order Linear Differential Equations
    • 3.18
      Time Response of Linear Dynamical Systems
    • 3.19
      Stability of Linear Time Invariant Systems
    • 3.20
      Controllability and Observability of linear Time Invariant Systems
    • 3.21
      Pole Placement Control Design
    • 3.22
      Pole Placement Observer Design
    • 3.23
      Static Optimization: An Overview
    • 3.24
      Calculus of Variations: An Overview
    • 3.25
      Optimal Control Formulation using Calculus of Variations
    • 3.26
      Classical Numerical Methods for Optimal Control
    • 3.27
      Linear Quadratic Regulator (LQR) Design – 1
    • 3.28
      Linear Quadratic Regulator (LQR) Design – 2
    • 3.29
      Linear Control Design Techniques in Aircraft Control – I
    • 3.30
      Linear Control Design Techniques in Aircraft Control – I
    • 3.31
      Lyapunov Theory – I
    • 3.32
      Lyapunov Theory -II
    • 3.33
      Constructions of Lyapunov Functions
    • 3.34
      Dynamic Inversion – I
    • 3.35
      Dynamic Inversion – II
    • 3.36
      Neuro-Adaptive Design -I
    • 3.37
      Neuro-Adaptive Design — II
    • 3.38
      Neuro-Adaptive Design for Flight Control
    • 3.39
      Integrator Back-Stepping & Linear Quadratic (lQ) Observer
    • 3.40
      An Overview of Kalman Filter Theory
  • Advanced Finite Elements Analysis
    30
    • 4.1
      Lecture – 1
    • 4.2
      Lecture – 2
    • 4.3
      Lecture – 3
    • 4.4
      Lecture – 4
    • 4.5
      Lecture – 5
    • 4.6
      Lecture – 6
    • 4.7
      Lecture – 7
    • 4.8
      Lecture – 8
    • 4.9
      Lecture – 9
    • 4.10
      Lecture – 10
    • 4.11
      Lecture – 11
    • 4.12
      Lecture – 12
    • 4.13
      Lecture – 13
    • 4.14
      Lecture – 14
    • 4.15
      Lecture – 15
    • 4.16
      Lecture – 16
    • 4.17
      Lecture – 17
    • 4.18
      Lecture – 18
    • 4.19
      Lecture – 19
    • 4.20
      Lecture – 20
    • 4.21
      Lecture – 21
    • 4.22
      Lecture – 22
    • 4.23
      Lecture – 23
    • 4.24
      Lecture – 24
    • 4.25
      Lecture – 25
    • 4.26
      Lecture – 26
    • 4.27
      Lecture – 27
    • 4.28
      Lecture – 28
    • 4.29
      Lecture – 29
    • 4.30
      Lecture – 30
  • Aero Elasticity
    26
    • 5.1
      Lecture 1
    • 5.2
      Lecture 2
    • 5.3
      Lecture 3
    • 5.4
      Lecture 4
    • 5.5
      Lecture 5
    • 5.6
      Lecture 6
    • 5.7
      Lecture 7
    • 5.8
      Lecture 8
    • 5.9
      Lecture 9
    • 5.10
      Lecture 10
    • 5.11
      Lecture 11
    • 5.12
      Lecture 12
    • 5.13
      Lecture 13
    • 5.14
      Lecture 14
    • 5.15
      Lecture 15
    • 5.16
      Lecture 16
    • 5.17
      Lecture 17
    • 5.18
      Lecture 18
    • 5.19
      Lecture 19
    • 5.20
      Lecture 20
    • 5.21
      Lecture 21
    • 5.22
      Lecture 22
    • 5.23
      Lecture 23
    • 5.24
      Lecture 24
    • 5.25
      Lecture 25
    • 5.26
      Lecture 26
  • Aerospace Propulsions
    42
    • 6.1
      Introduction
    • 6.2
      Air breathing Engines Turbojet I
    • 6.3
      Air breathing Engines Turbojet II
    • 6.4
      Air breathing Engines Turboprop & Turbofan
    • 6.5
      Air breathing Engines Ramjet & Scramjet
    • 6.6
      Non-air breathing Engines I
    • 6.7
      Non-air breathing Engines II
    • 6.8
      General Performance Parameters I
    • 6.9
      General Performance Parameters II
    • 6.10
      Cycle Analysis Ramjet
    • 6.11
      Cycle Analysis Turbojet I
    • 6.12
      Cycle Analysis Turbojet II
    • 6.13
      Cycle Analysis Turbojet III
    • 6.14
      Cycle Analysis Turbojet IV
    • 6.15
      Cycle Analysis Turbojet V
    • 6.16
      Cycle Analysis Turbojet VI
    • 6.17
      Cycle Analysis Turbofan
    • 6.18
      Rocket Nozzles 1D Analysis I
    • 6.19
      Rocket Nozzles 1D Analysis II
    • 6.20
      Rocket Nozzles 1D Analysis III
    • 6.21
      Rocket Nozzles Real Effects I
    • 6.22
      Rocket Nozzles Real Effects II
    • 6.23
      Rocket Nozzles Thrust Vectoring
    • 6.24
      Solid Rockets Propellants
    • 6.25
      Solid Rockets Burn rate
    • 6.26
      Solid Rockets Performance
    • 6.27
      Solid Rockets Grain
    • 6.28
      Solid Rockets Ignition, Quenching
    • 6.29
      Solid Rockets Igniter, Depressurization
    • 6.30
      Propellant Combustion Combustion Modelling
    • 6.31
      Liquid Rocket Propellants
    • 6.32
      Liquid Rocket Nozzle Cooling I
    • 6.33
      Liquid Rocket Nozzle Cooling II
    • 6.34
      Liquid Rocket Nozzle Cooling III
    • 6.35
      Liquid Rocket Pressure fed system
    • 6.36
      Liquid Rocket Pump fed system
    • 6.37
      Liquid Rocket Pumps
    • 6.38
      Liquid Rocket Fuel Injection
    • 6.39
      Hybrid Rocket Basics
    • 6.40
      Hybrid Rocket Performance
    • 6.41
      Hybrid Rocket Combustion
    • 6.42
      Chemical Equilibrium Analyser SP 273
  • Basic Electronics
    40
    • 7.1
      Lecture 1: Semiconductor materials
    • 7.2
      Lecture 2: PN Junction Diodes
    • 7.3
      Lecture 3: Diode Equivalent Circuits
    • 7.4
      Lecture 4: Diode Rectifier Circuits
    • 7.5
      Lecture 5: Zener Diode and Applications
    • 7.6
      Lecture 6: Clipping and Clamping Circuits
    • 7.7
      Lecture 7: Transistor Operation – Part – 1
    • 7.8
      Lecture 8: Transistor Operation Part – 2
    • 7.9
      Lecture 9: Biasing the BJT – Part – 1
    • 7.10
      Lecture 10: Biasing the BJT – Part – 2
    • 7.11
      Lecture 11: BJT Small Signal Analysis
    • 7.12
      Lecture 12: BJT Amplifier – Part – 1
    • 7.13
      Lecture 13: BJT Amplifier Part – 2
    • 7.14
      Lecture 14: Frequency Response of BJT Analysis – Part – 1
    • 7.15
      Lecture 15: Frequency Response of BJT Analysis Part – 2
    • 7.16
      Lecture 16: Transistor as a Switch
    • 7.17
      Lecture 17: Metal Oxide Semiconductor Field Transistors- 1
    • 7.18
      Lecture 18: Metal Oxide Semiconductor Field Transistors- 2
    • 7.19
      Lecture 19: MOSFET under dc operation
    • 7.20
      Lecture 20: MOSFET as an Amplifier
    • 7.21
      Lecture 21: Small signal model of MOSFET – I
    • 7.22
      Lecture 22: Small signal model of MOSFET – II
    • 7.23
      Lecture 23: High Frequency model of MOSFET
    • 7.24
      Lecture 24: Junction Field Effect Transistor
    • 7.25
      Lecture 25: Operational Amplifier (Op-Amp)
    • 7.26
      Lecture 26: Ideal Op-Amp
    • 7.27
      Lecture 27: Op-Amp applications – I
    • 7.28
      Lecture 28: Op-Amp applications
    • 7.29
      Lecture 29: Op-Amp applications – III
    • 7.30
      Lecture 30: The practical Op-Amp
    • 7.31
      Lecture 31: Positive feedback and oscillation
    • 7.32
      Lecture 32: Comparator
    • 7.33
      Lecture 33: Large Signal Amplifiers
    • 7.34
      Lecture 34: Transformer Coupled Power Amplifier
    • 7.35
      Lecture 35: Class AB Operations of PowerAmplifier
    • 7.36
      Lecture 36: Power BJTs
    • 7.37
      Lecture 37: Regulated Power Supply
    • 7.38
      Lecture 38: Four Layered Diode
    • 7.39
      Lecture 39: Silicon Control Rectifier
    • 7.40
      Lecture 40: SCR Applications
  • Basic Thermodynamics
    32
    • 8.1
      Lec-1 Introduction and Fundamental Concepts
    • 8.2
      Lec-2 Zeroth Law and Fundamental Concepts
    • 8.3
      Lec- 3 Different Kind of Energy & First Law-I
    • 8.4
      Lec-4 First Law-II
    • 8.5
      Lec-5 First Law-III
    • 8.6
      Lec-6 Second Law & Its Corollaries-I
    • 8.7
      Lec-7 Second Law & Its Corollaries-II
    • 8.8
      Lec-8 Second Law & Its Corollaries-III
    • 8.9
      Lec-9 Second Law & Its Corollaries-IV
    • 8.10
      Lec-10 Second Law & Available Energy-I
    • 8.11
      Lec-11 Second Law & Available Energy-II
    • 8.12
      Lec-12 Second Law & Available Energy-III
    • 8.13
      Lec-13 Thermodynamic Property Relations-I
    • 8.14
      Lec-14 Thermodynamic Property Relations-II
    • 8.15
      Lec-15 Joule-Kelvin Expansion:Properties of Pure Substances
    • 8.16
      Lec-16 Properties of Pure Substances-I
    • 8.17
      Lec-17 Properties of Pure Substances-II
    • 8.18
      Lec-18 Properties of Pure Substances: Ideal Gases
    • 8.19
      Lec-19 Properties of Ideal Gases
    • 8.20
      Lec-20 Vapors Power Cycle-I
    • 8.21
      Lec-21 Vapor Power Cycle-II
    • 8.22
      Lec-22 Vapor Power Cycle-III
    • 8.23
      Lec-23 Vapor Power Cycle-IV
    • 8.24
      Lec-24 Gas Power Cycle-I
    • 8.25
      Lec-25 Gas Power Cycle-II
    • 8.26
      Lec-26 Gas Power Cycle-III
    • 8.27
      Lec-27 Thermodynamics of Reacting System-I
    • 8.28
      Lec-28 Thermodynamics of Reacting System-II
    • 8.29
      Lec-29 Thermodynamics of Reacting System-III
    • 8.30
      Lec-30 Thermodynamics of Multi Component System-I
    • 8.31
      Lec-31 Thermodynamics of Multi Component System-II
    • 8.32
      Lec-32 Thermodynamics of Multi Component System-III
  • Combustion
    36
    • 9.1
      Thermodynamics-Lecture 1 : Introduction
    • 9.2
      Thermodynamics-Lecture 2 : Chemical Reactions, Heats of Reaction and Formation
    • 9.3
      Thermodynamics-Lecture 3 : Sensible Enthalpy and Adiabatic Flame Temperature
    • 9.4
      Thermodynamics-Lecture 4 : Dissociation of Products, Role of Pressure
    • 9.5
      Thermodynamics-Lecture 5 : Numerical Calculation of Adiabatic Flame Temperature, Chemical Kinetics 1
    • 9.6
      Chemical Kinetics-Lecture 6 : Chemical Kinetics 2
    • 9.7
      Chemical Kinetics-Lecture 7 : Equilibrium Reactions, Global Kinetics, Order of Reaction
    • 9.8
      Chemical Kinetics-Lecture 8 : Reduced Chemistry, Steady State Approximation
    • 9.9
      Chemical Kinetics-Lecture 9 : Steady State Approximation, Partial Equilibrium Approximation
    • 9.10
      Chemical Kinetics-Lecture 10: Partial Equilibrium Approximation, Chemical Explosions
    • 9.11
      Chemical Kinetics-Lecture 11: Combining Chemical and Thermal Processes 1
    • 9.12
      Chemical Kinetics-Lecture 12: Combining Chemical and Thermal Processes 2
    • 9.13
      Chemical Kinetics-Lecture 13: Combining Chemical and Thermal Processes 3
    • 9.14
      Chemical Kinetics-Lecture 14: Combining Chemical and Thermal Processes 4
    • 9.15
      Mass Transfer Definitions-Lecture 15: Mass and Molar Diffusion, Fick’s Law
    • 9.16
      Conservation Equations-Lecture 16: Conservation Equations for Multi-Component Mixtures
    • 9.17
      Conservation Equations-Lecture 17: Multi-Component Diffusion Equation
    • 9.18
      Conservation Equations-Lecture 18: Multi-Component Momentum Equation
    • 9.19
      Conservation Equations-Lecture 19: Energy Equation
    • 9.20
      Conservation Equations-Lecture 20: One Dimensional Steady Flow
    • 9.21
      Schvab-Zeldovich Formulation-Lecture 21: Schvab-Zeldovich Formulation 1
    • 9.22
      Schvab-Zeldovich Formulation-Lecture 22: Schvab-Zeldovich Formulation 2
    • 9.23
      Schvab-Zeldovich Formulation-Lecture 23: Rankine-Hugoniot Relations 1
    • 9.24
      Rankine-Hugoniot Relations-Lecture 24: Rankine-Hugoniot Relations 2
    • 9.25
      Rankine-Hugoniot Relations-Lecture 25: Rankine-Hugoniot Relations 3
    • 9.26
      Rankine-Hugoniot Relations-Lecture 26: Velocity, Temperature and Entropy Variation along Hugoniot Curve
    • 9.27
      Laminar Premixed Flames-Lecture 27: Laminar Premixed Flames
    • 9.28
      Laminar Premixed Flames-Lecture 28: Laminar Premixed Flames – Corrections
    • 9.29
      Laminar Premixed Flames-Lecture 29: Laminar Premixed Flames – Rigorous Analysis 1
    • 9.30
      Laminar Premixed Flames-Lecture 30: Laminar Premixed Flames – Rigorous Analysis 2
    • 9.31
      Laminar Premixed Flames-Lecture 31: Flame Speed Dependencies, G-Equation
    • 9.32
      Laminar Premixed Flames-Lecture 32: Bunsen Burner 1
    • 9.33
      Laminar Premixed Flames-Lecture 33: Bunsen Burner 2
    • 9.34
      Laminar Premixed Flames-Lecture 34: Flame Stabilisation 1
    • 9.35
      Laminar Premixed Flames-Lecture 35: Flame Stabilisation 2
    • 9.36
      Laminar Premixed Flames-Lecture 36: Ignition
  • Computer Graphics
    43
    • 10.1
      Lecture – 1 Introduction to computer graphics
    • 10.2
      Lecture 2: CRT Display Devices
    • 10.3
      Lecture 3: CRT display devices (Contd…)
    • 10.4
      Lecture 4: CRT display devices (Contd…)
    • 10.5
      Lecture 5: CRT display devices (Contd…)
    • 10.6
      Lecture 6: Transformations in 2D
    • 10.7
      Lecture 7: Transformations in 2D (Contd…)
    • 10.8
      Lecture 8: Three Dimensional Graphics
    • 10.9
      Lecture 9: Three Dimensional Graphics (Contd…)
    • 10.10
      Lecture 10: Three Dimensional Graphics (Contd…)
    • 10.11
      Lecture 11: Project Transformations and Viewing Pipeline
    • 10.12
      Lecture 12: 3D Viewing – Projection Transformations And Viewing Pipeline
    • 10.13
      Lecture 13: Scan Converting Lines, Circles and Ellipses I
    • 10.14
      Lecture 14: Scan Converting Lines, Circles and Ellipses II
    • 10.15
      Lecture 15: Scan Converting Lines, Circles and Ellipses III
    • 10.16
      Lecture 16: Scan Converting Lines, Circles and Ellipses IV
    • 10.17
      Lecture 17: Scan Converting Lines, Circles and Ellipses V
    • 10.18
      Lecture 18: PolyFill Scan Conversion of a Polygon
    • 10.19
      Lecture 19: Scan Conversion Of A Polygon (Contd)
    • 10.20
      Lecture 20: Clipping Lines And Polygons
    • 10.21
      Lecture 21: Clipping: Lines and Polygon
    • 10.22
      Lecture 22: Clipping Lines
    • 10.23
      Lecture 23: Solid Modelling
    • 10.24
      Lecture 24: Solid Modelling (Contd…)
    • 10.25
      Lecture 25: Solid Modelling (Contd…)
    • 10.26
      Lecture 26: Visible Surface Detection
    • 10.27
      Lecture 27: Visible Surface Detection (Contd…)
    • 10.28
      Lecture 28: Visible Surface Detection (Contd…)
    • 10.29
      Lecture 29: Visible Surface Detection (Contd…)
    • 10.30
      Lecture 30: Visible Surface Detection (Contd…)
    • 10.31
      Lecture 31: Visible Surface Detection (Contd…)
    • 10.32
      Lecture 32: Visible Surface Detection (Contd…)
    • 10.33
      Lecture 33: Illumination and Shading
    • 10.34
      Lecture 34: Illumination and Shading (Contd….)
    • 10.35
      Lecture 35: Illumination and Shading (Contd….)
    • 10.36
      Lecture 36: Curve Representation
    • 10.37
      Lecture 37: Curve Representation (Contd…)
    • 10.38
      Lecture 38: Curves and Surface Representation
    • 10.39
      Lecture 39: Graphics Programming
    • 10.40
      Lecture 40: Graphics Programming Using OpenGL
    • 10.41
      Lecture 41: Anti Aliasing,Color,Soft Objects, Animation, Visual Effects,System Architectures
    • 10.42
      Lecture 42: Digital Image Processing
    • 10.43
      Lecture 43: Digital Image Processing (Contd…)
  • Computer Graphics
    43
    • 11.1
      Lecture 1: Introduction
    • 11.2
      Lecture-2 Raster Graphics
    • 11.3
      Lecture – 3 Raster Graphics (Contd.)
    • 11.4
      Lecture – 4 Clipping
    • 11.5
      Lecture -5 Polygon Clipping and Polygon Scan Conversion
    • 11.6
      Lecture – 6 Transformations
    • 11.7
      Lecture – 7 Transformations (Contd.)
    • 11.8
      Lecture – 8 3D Viewing
    • 11.9
      Lecture – 9 3D Viewing (Contd.)
    • 11.10
      Lecture – 10 Curves
    • 11.11
      Lecture – 11 Assignment 1
    • 11.12
      Lecture – 12 Curves
    • 11.13
      Lecture – 13 Curves (Contd.)
    • 11.14
      Lecture – 14 Curves (Contd.)
    • 11.15
      Lecture – 15 Curves (Contd.)
    • 11.16
      Lecture – 16 Surfaces
    • 11.17
      Lecture – 17 Surface (Contd.)
    • 11.18
      Lecture – 18 Surfaces (Contd.)
    • 11.19
      Lecture – 19 Surfaces (Contd.)
    • 11.20
      Lecture – 20 Hierarchical Models
    • 11.21
      Lecture – 21 Rendering
    • 11.22
      Lecture – 22 Rendering (Contd.)
    • 11.23
      Lecture – 23 Rendering (Contd.)
    • 11.24
      Lecture – 24 Ray Tracing
    • 11.25
      Lecture – 25 Ray Tracing (Contd.)
    • 11.26
      Lecture – 26 Ray Tracing (Contd.)
    • 11.27
      Lecture – 27 Assignment: Ray Tracing
    • 11.28
      Lec-28 Hidden Surface Elimination
    • 11.29
      Lecture -29 Hidden Surface Elimination (Contd.)
    • 11.30
      Lec-30 Hidden Surface Elimination(Contd.)
    • 11.31
      Lec-31 Fractals
    • 11.32
      Lecture – 32 Fractals (Contd.)
    • 11.33
      Lecture – 33 Computer Animation
    • 11.34
      Lecture – 34 Animation (Contd.)
    • 11.35
      Lecture – 35 Animation (Contd.)
    • 11.36
      Lecture – 36 Curve Representation
    • 11.37
      Lecture – 37 Curve Representation
    • 11.38
      Lecture – 38 Curves and Surface Representation
    • 11.39
      Lecture – 39 Graphics Programming
    • 11.40
      Lecture – 40 Graphics Programming Using OpenGL
    • 11.41
      Lecture – 41 Advanced Topics
    • 11.42
      Lecture – 42 Digital Image Processing
    • 11.43
      Lecture – 43 Digital Image Processing
  • Database Management System
    42
    • 12.1
      Conceptual Designs Part 1
    • 12.2
      Conceptual Designs Part 2
    • 12.3
      Relational Model Part 1
    • 12.4
      Relational Model Part 2
    • 12.5
      Structured Query Language Part 1
    • 12.6
      Structured Query Language Part 2
    • 12.7
      ER Model to Relational Mapping
    • 12.8
      Functional Dependencies & Normal Form
    • 12.9
      ER Model to Relational Model Maping
    • 12.10
      Storage Structures
    • 12.11
      Indexing Techniques Single Level
    • 12.12
      Indexing Techniques Multi-Level
    • 12.13
      Constraints & Triggers
    • 12.14
      Query Processing & Optimization Part 1
    • 12.15
      Query Processing & Optimization Part 2
    • 12.16
      Query Processing & Optimization Part 3
    • 12.17
      Transaction Processing Concepts
    • 12.18
      Transaction Processing & Database Manager
    • 12.19
      Foundation for Concurrency Control
    • 12.20
      Concurrency Control Part 1
    • 12.21
      Concurrency Control Part 2
    • 12.22
      Concurrency Control Part 3
    • 12.23
      Concurrency Control Part 4
    • 12.24
      Distributed Transaction Models
    • 12.25
      Basic 2-Phase & 3-Phase Commit Protocol
    • 12.26
      Concurrency Control for Distributed Transaction
    • 12.27
      Introduction to Transaction Recovery
    • 12.28
      Recovery Mechanisms Part 1
    • 12.29
      Recovery Mechanisms Part 2
    • 12.30
      Introduction to Data Warehousing & OLAP Part 1
    • 12.31
      Introduction to Data Warehousing & OLAP Part 2
    • 12.32
      Case Study : MYSQL
    • 12.33
      Case Study : ORACLE & Microsoft Access
    • 12.34
      Data Mining & Knowledge Discovery Part 1
    • 12.35
      Data Mining & Knowledge Discovery Part 2
    • 12.36
      Object Oriented Databases Part 1
    • 12.37
      Object Oriented Databases Part 2
    • 12.38
      XML – Introductory Concepts
    • 12.39
      XML Advanced Concepts
    • 12.40
      XML Databases
    • 12.41
      Case Study – Database Design Part 1
    • 12.42
      Case Study – Database Design Part 2
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Lecture 27: Op-Amp applications – I
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