Skip to content
Any One Study
  • HOME
  • FAQ
  • ABOUTExpand
    • About Company
    • Vision and Mission
    • Our Team
    • Privacy Policy
    • Terms of Use
  • CONTACT
  • SMART HEALTHExpand
    • Online Health Assistance from Indian Doctors and Specialist . Live Video Consultation
  • BUY NOW
  • LOGIN
  • Register
Live Assistance
Any One Study
  • Home
  • Courses
  • Engineering

Aeronautical Engineering

Curriculum

  • 11 Sections
  • 415 Lessons
  • 10 Weeks
Expand all sectionsCollapse all sections
  • 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
This content is protected, please login and enroll in the course to view this content!
Time Response of Linear Dynamical Systems
Prev
Controllability and Observability of linear Time Invariant Systems
Next

© 2026 Any One Study 

  • HOME
  • FAQ
  • ABOUT
  • CONTACT
  • SMART HEALTH
  • BUY NOW
  • LOGIN
  • Register
Facebook Twitter Instagram YouTube
  • HOME
  • FAQ
  • ABOUT
    • About Company
    • Vision and Mission
    • Our Team
    • Privacy Policy
    • Terms of Use
  • CONTACT
  • SMART HEALTH
    • Online Health Assistance from Indian Doctors and Specialist . Live Video Consultation
  • BUY NOW
  • LOGIN
  • Register