subjectId
Discipline Name
Subject Name
Coordinators
Type
Institute
Content
101101001
Aerospace Engineering
Introduction to Aerospace Propulsion
Prof. A M Pradeep ,Prof. Bhaskar Roy
Video
IIT Bombay
Select
L1-Course Intro & Historical development of flights
L2-Early development of aircraft propulsive devices
L3-Development of Jet propulsion for aircraft
L4- Introduction to thermodynamics, Scope and method, Basic concepts: system, surroundings, property, intensive and extensive, state, equilibrium and state postulate, process, path and cycle
L5- Quasi-static processes, zeroth law of thermodynamics and temperature, concept of energy and its various forms, internal energy, enthalpy
L6- Specific heats at constant pressure and volume Work and heat transfers
L7- Tutorial
L8- First law of thermodynamics for closed systems
L9- First law of thermodynamics for open systems/flow processes
L10-Second law of thermodynamics, heat engines, refrigerators and heat pumps, Kelvin-Planck and Clausius statement of second law of thermodynamics
L11- Reversible and irreversible processes, concept of entropy
L12- Increase of entropy principle, third law of thermodynamics, absolute entropy, perpetual motion machines
L13- Tutorial
L14- Carnot cycle, Carnot principle, thermodynamic temperature scale
L15- Exergy, availability and second law efficiency
L16- Tutorial
L17- Gas and vapour power cycles, Otto cycle, Diesel cycle, Dual cycle
L18- Rankine cycle, Brayton cycle, Stirling and Ericsson cycles
L19- Thermodynamic property relations, Jacobean and Legendre transformations, Maxwell�s equations
L20- Tutorial
L21- Properties of gas and vapour mixtures
L22 (A)- One-dimensional compressible flows, isentropic flows
L22 (B)- Flows with friction and heat transfer, normal and oblique shocks
L23- Piston-prop engines: Otto cycles; Ideal and Real cycles
L24- IC Engines for aircraft application
L25- Performance parameters of IC engines
L26- Supercharging of aircraft IC engines
L27- Tutorial: IC Engines
L28- Propeller fundamentals
L29- Propeller aerodynamic theories �I
L30- Propeller aerodynamic theories �II
L31- Tutorial: Propellers
L32- Ideal cycles for Jet engines
L33- Ideal cycles for variants of jet engines
L34- Tutorial
L35- Fundamentals of Ramjets and Pulsejets
L36- Fundamentals of Rocket engines
L37- Fundamentals of Missile engines
L38- Various space vehicles and their engines
L39- Closure of the lecture series : recap
101101002
Aerospace Engineering
Jet Aircraft Propulsion
Prof. Bhaskar Roy,Prof. A M Pradeep
Video
IIT Bombay
Select
L1-Introduction & Development of Jet Aircraft Propulsion
L2-How the Aircraft Jet Engines make Thrust
L3-Jet Engine Basic Performance Parameters
L4-Turbojet, Reheat Turbojet and Multi-spool Engines
L5-Turbofan, Turbo-prop and Turboshaft engines
L6-Ideal and Real Brayton cycles
L7-Jet Engine Cycles for Aircraft propulsion
L8-Cycle components and component performances
L9-Tute-1
L10-Analysis of engine real cycles
L11-Tute-2
L12-Thermodynamics of Compressors
L13-Thermodynamics of Turbines
L14-Axial Compressors : two dimensional analytical model
L15-Cascade analysis; Loss and Blade performance estimation
L16-Free Vortex theory; Single-Multi-stage characteristics
L17-Tutes � 3
L18-Elements of centrifugal compressor
L19-Centrifugal Compressor characteristics: Surging, Choking
L20-Axial flow turbines; Turbine Blade 2-D (cascade) analysis
L21-Multi-staging: Axial Turbine; Turbine Cooling Technology
L22-Radial Turbine Aerodynamics & Thermodynamics; Losses
L23-Tutes � 4
L24-Types of combustion chambers: mechanism & parameters
L25-Pr. Loss, Combustion efficiency; Combustion intensity
L26-Practical combustion system ; Stability, Fuel injection
L27-Intakes for Powerplant: Transport / Military Aircraft
L28-Subsonic, Transonic, Supersonic Intake Designs
L29-Nozzle : fixed and variable geometry nozzles
L30-C-D nozzle and their uses
L31-Tute-5
L32-Engine Off Design Operations
L33-Aircraft Engine component matching: Dimensional analysis
L34-Engine component matching and Sizing
L35-Installed Performance of Engine
L36-Tute-6
L37-Use of Ramjets and Pulsejets in Aircraft propulsion
L38-Thermodynamic Cycle & Performance Parameters
L39-Flow in Diffusers, Combustors and Nozzles
L40-Performanace and Design of Ramjet & Scramjet Engines
L41-Tute � 7
L42-Future of Aircraft Propulsion
101101058
Aerospace Engineering
Turbomachinery Aerodynamics
Prof. A M Pradeep ,Prof. Bhaskar Roy
Video
IIT Bombay
Select
L1-Introduction to Turbo machines Syllabus, References and Schedules
L2-Axial Flow Compressors and Fans : Introduction to Compressor Aerothermodynamics
L3-A two dimensional analytical model :Cascade
L4-2D losses in Axial flow Compressor Stage : Primary losses
L5-Tutorial 1 : Two Dimensional Axial Flow Compressors
L6-3D Flows in Blade Passages, Secondary Flows, Tip leakage Flow, Scrubbling
L7-Three Dimensional Flow Analysis : Radial Equilibrium Concept
L8-Classical Blade Design Laws : Free Vortex and other Laws
L9-Three Dimensional Flow Analysis in Axial Flow Compressor
L10-Tutorial 2: Three Dimensional Axial Flow Compressors
L11-Axial Compressor Characteristics: Single stage, Multi stage and Multi spool Characteristics
L12-Instability in Axial Compressors
L13-Inlet Distortion and Rotating Stall, Control of Instability
L14-Transonic Compressors and Shock Structure Models, Transonic Compressor Characteristics
L15-Axial Flow Compressor Design, Inter Spool Duct
L16-Design of Compressor Blades, Aerofoil Design (Subsonic, Transonic, Supersonic Profiles )
L17-Design of Compressor Blade: 3D Blade Shapes of Rotors and Stators
L18-Noise Problem in Axial Compressors and Fans
L19-Axial Flow Turbines: Introduction to Turbines Aerothermodynamics
L20-Axial Flow Turbines: Turbine Blade 2D (Cascade) Analysis
L21-Axial Flow Turbines: Work done, Degree of Reaction, Losses and Efficiency
L22-Axial Flow Turbines: Blade and Axial Flow Passages, Exit Flow Matching with Nozzle
L23-Tutorial 3 : Axial Flow Turbines
L24-Multi staging and Multi spooling of Turbine
L25-3D Flow in Turbine: 3D Flow Theories, Free Vortex Theories etc.
L26-Tutorial 4 : 3D Flows in Axial Flow Turbines
L27-Turbine Blade Cooling � Fundamentals of Heat Transfer, Blade Cooling Requirements
L28-Turbine Blade Cooling Technologies
L29-Turbine Blade Design: Turbine Profiles, Aerofoil Data and Profile Construction
L30-Turbine Blade Design: 3D Blade Shapes
L31-Centrifugal Compressors: Thermodynamics and Aerodynamics
L32-Centrifugal Compressors : Characteristics, Stall, Surge Problems
L33-Tutorial 5 : Centrifugal Compressors
L34-Design of Centrifugal Compressors: Impellers, Vane/Vane less Diffusers, Volutes
L35-Radial Turbines: Thermodynamics and Aerodynamics
L36-Tutorial 6 : Radial Turbines
L37-Radial Turbine Characteristics and Design of Radial Turbines
L38-CFD for Turbomachinery: Grid Generation, Boundary Conditions for Flow Analysis
L39-CFD for Turbomachinery: Flow Track and Inter-spool Duct Design using CFD
L40-CFD for Turbomachinery: 2D and 3D Blade Generation and Analysis Using CFD
101104005
Aerospace Engineering
Aero elasticity
Prof. C. Venkatesan
Video
IIT Kanpur
Select
Lecture-01-Aero elasticity
Lecture-02-Aero elasticity
Lecture-03-Aero elasticity
Lecture-04-Aero elasticity
Lecture-05-Aero elasticity
Lecture-06-Aero elasticity
Lecture-07-Aero elasticity
Lecture-08-Aero elasticity
Lecture-09-Aero elasticity
Lecture-10-Aero elasticity
Lecture-11-Aero elasticity
Lecture-12-Aero elasticity
Lecture-13-Aero elasticity
Lecture-14-Aero elasticity
Lecture-15-Aero elasticity
Lecture-16-Aero elasticity
Lecture-17-Aero elasticity
Lecture-18-Aero elasticity
Lecture-19-Aero elasticity
Lecture-20-Aero elasticity
Lecture-21-Aero elasticity
Lecture-22-Aero elasticity
Lecture-23-Aero elasticity
Lecture-24-Aero elasticity
Lecture-25-Aero elasticity
Lecture-26-Aero elasticity
101103003
Aerospace Engineering
Hypersonic Aerodynamics
Dr. N. Sahoo , Dr. Vinayak Kulkarni
Web
IIT Guwahati
Select
Characteristics of Hypersonic Atmosphere
Mass Conservation Equation
Linear Momentum Conservation Equation I
Linear Momentum Conservation Equation II
Energy Conservation Equation
Species Conservation Equation
Hypersonic flow relations I
Hypersonic flow relations II
Local Surface Inclination technique (Newtonian Technique)
Local Surface Inclination techniques (Modified Newtonian Technique)
Tangent wedge and tangent cone methods
Hypersonic Mach number independence principle I
Hypersonic Mach number independence principle II
The Hypersonic Small Disturbance Theory I
The Hypersonic Small Disturbance Theory II
The Hypersonic Equivalence Principles
Blast Wave Theory I
Blast Wave Theory II
Thin Shock Layer Theory
Hypersonic boundary equation
Non-dimensionalisation of governing equations
Order of magnitude estimate
Boundary layer equations
Similarity solution for boundary layer equation I
Similarity solution for boundary layer equation II
Similarity solution of boundary layer equation
Hypersonic flow over flat plate
Stagnation point flow field
Hypersonic Viscous Interaction I
Hypersonic Viscous Interaction II
Hypersonic wind tunnel
Hypersonic wind tunnel and its calibration
Hypersonic impulse facilities
Shock Tunnel and its variants
Piston based shock Tunnels
Other hypersonic test facilities
Heat transfer rate measurement
Force measurement
Hypersonic vehicle cooling strategies
Drag reduction methods
Hypersonic flight parameters and stability
Equilibrium flows
Special topics in hypersonics
References
101103004
Aerospace Engineering
Principles of Fluid Dynamics
Dr. Vinayak Kulkarni, Dr. N. Sahoo
Web
IIT Kanpur
Select
Basic Concepts
Review of Fluid Statics
Fundamental Aspects I
Integral Form-Part I
Integral Form-Part I(i)
Integral Form-Part I(ii)
Differential Form-Part I
Differential Form-Part I(i)
Differential Form-Part I(ii)
Fundamental Aspects II
Kinematic Description Of Fluid Flow
Stream Function And Velocity Potential
Basic Potential Flows � I
Basic Potential Flows � I(i)
Superposition Of Potential Flows � I
Superposition Of Potential Flows � I(i)
Superposition Of Potential Flows � Iii
Fundamental Aspects: Part � I
Fundamental Aspects: Part � I(i)
Isentropic And Characteristics States
One-Dimensional Analysis
Two-Dimensional Analysis
Hypersonic Flow: Part � I
Hypersonic Flow: Part � I(i)
Hypersonic Flow: Part � I(ii)
Fundamental Aspects
Internal Flow � Part I
Internal Flow � Part I(i)
Internal Flow � Part I(ii)
Internal Flow � Part I(v)
Internal Flow � Part V
External Flow � Part I
External Flow � Part I(i)
External Flow � Part I(ii)
External Flow � Part I(v)
External Flow � Part V
Dimensionsl Analysis�I
Dimensionsl Analysis-Ii
Incompressible Flow � Part I
Incompressible Flow � Part I(i)
Incompressible Flow � Part Iii
Incompressible Flow � Part Iv
Compressible Flow � Part I
Compressible Flow � Part I(i)
Compressible Flow � Part I(ii)
Aerodynamics Test Facilities - Part I
Aerodynamics Test Facilities - Part Ii
Problem I
Problem II
Problem III
Problem IV
Problem V
Problem VI
Problem VII
Problem VIII
101104010
Aerospace Engineering
Composite Materials and Structure
Dr. P.M. Mohite
Web
IIT Kanpur
Select
Definition and Introduction
Reinforcement: Materials and Forms
Reinforcement: Materials
Matrix Materials
Terminologies
Applications
Fabrication Processes
Fabrication Processes
Basic Concepts
Constitutive Relations: Generally Anisotropy to Orthotropy
Constitutive Relations: Transverse Isotropy and Isotropy
Constitutive Relations for Orthotropic Materials and Stress-Strain Transformations
Stiffness, Compliance Transformation and Hygro-thermo-elastic Constitutive Relation
2-Dimensional Lamina Analysis
Lamina Engineering Constants
Introduction to Classical Plate Theory
Laminate Constitutive Relations
Laminate Engineering Constants
Hygro -thermal Laminate Theory
Damage Mechanisms in Unidirectional Composites
Macroscopic Failure Theories
Macroscopic Failure Theories
Macroscopic Failure Theories
Tensile Fibre Mode Compressive Fibre Mode
Strength of Materials Approach
Concepts of Equivalent Homogeneity, Volumetric Averaging and Standard Mechanics
Hill's Concentration Factors Approach
Homogenization
Background of Concentric Cylinder Assemblage Model
CCA Model: Effective Axial Modulus and Poisson's Ratio
CCA Model: Effective Plane Strain Bulk Modulus
CCA Model: Effective Axial Shear Modulus
Three Phase CCA Model: Effective Transverse Shear Modulus
Self Consistent, Mori -Tanaka and Halpin -Tsai Models
Background to Mechanical Testing
Quality Assessment and Physical Properties
Tensile and Compressive Testing
Shear Testing
Shear and Flexural Testing
Design Considerations in Composites
101104013
Aerospace Engineering
Foundation of Scientific Computing
Prof. Tapan K. Sengupta
Video
IIT Kanpur
Select
Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
Lecture-27
Lecture-28
Lecture-29
Lecture-30
Lecture-31
Lecture-32
Lecture-33
Lecture-34
Lecture-35
Lecture-36
Lecture-37
Lecture-38
Lecture-39
Lecture-40
101104014
Aerospace Engineering
Fundamentals of Combustion
Dr. D.P. Mishra
Web
IIT Kanpur
Select
Introduction
What is Fuel and Oxidizer?
Fuels
Characterization of Solid Fuels
Scope of Combustion
Thermodynamic Laws
Stoichiometry
Heat of Combustion
Adiabatic Flame Temperature
Chemical Equilibrium
Transport properties for gas mixture
Momentum conservation equation
Energy transport equation
Boundary layer solutions
Transport in Turbulent Flow
Law of Mass Action
Order reaction
Chain Branching Explosion
Structure of 1D Premixed Flame
Tube Method
Effect of Oxygen Concentration on SL
Flammability Limits
Flame Stabilization
Theoretical Analysis
Mechanism of Soot Formation
Overall mass conservation
The Temperature Profile
Spray Combustion Model
Solid Fuel Combustion
Atmosphere
Major Sources of CO Emission
Species Emission and Its Corrected Value
Emission and Its Control
Combustion Modification Methods
Introduction Thermodynamics Combustion
Introduction to Physics Combustion
Introduction to Chemistry Combustion
Introduction to Premixed Flame
Introduction to Diffusion Flame
Introduction to Combustion and Environment
101104015
Aerospace Engineering
Instability and Transition of Fluid Flows
Prof. Tapan K. Sengupta
Video
IIT Kanpur
Select
Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
Lecture-27
Lecture-28
Lecture-29
Lecture-30
Lecture-31
Lecture-32
Lecture-33
Lecture-34
Lecture-35
Lecture-36
Lecture-37
Lecture-38
Lecture-39
101104017
Aerospace Engineering
Introduction to Helicopter Aerodynamics and Dynamics
Prof. A.R. Manjunath,Prof. C. Venkatesan
Video
IIT Kanpur
Select
Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
101105023
Aerospace Engineering
High Speed Aero Dynamics
Dr. K.P. Sinhamahapatra
Web
IIT Kharagpur
Select
Compressible Aerodynamics
Compressible Aerodynamics (Contd.)
One-dimensional gas dynamics
One-dimensional gas dynamics (Contd.)
One-dimensional gas dynamics (Contd.)
One-dimensional gas dynamics (Contd.)
One-dimensional gas dynamics (Contd.)
One-dimensional gas dynamics (Contd. )
One-dimensional gas dynamics (Contd.)
One - dimensional gas dynamics (Contd.)
Waves in supersonic flow
Waves in supersonic flow (Contd.)
Waves in supersonic flow (Contd.)
Waves in supersonic flow (Contd.)
Waves in supersonic flow ( Contd.)
Waves in supersonic flow ( Contd.)
Waves in supersonic flow (Contd.)
Flow in ducts, (Nozzles and diffusers) and wind tunnels
Flow in ducts, (Nozzles and diffusers) and wind tunnels (Contd.)
Flow in ducts, (Nozzles and diffusers) and wind tunnels (Contd.)
Flow in ducts, (Nozzles and diffusers) and wind tunnels (Contd.)
Flow in ducts, (Nozzles and diffusers) and wind tunnels ( Contd.)
Multi-dimensional problems
Multi-dimensional problems (Contd.)
Multi-dimensional problems (Contd.)
Bodies of Revolution � Slender Body Theory
Bodies of Revolution � Slender Body Theory (Contd.)
Bodies of Revolution � Slender Body Theory (Contd.)
Bodies of Revolution � Slender Body Theory (Contd.)
Bodies of Revolution � Slender Body Theory (Contd.)
Bodies of Revolution � Slender Body Theory (Contd.)
Similarity Rules
Similarity Rules (Contd.)
Similarity Rules (Contd.)
Transonic Flow
Transonic Flow (Contd.)
Method of characteristics
Method of characteristics (Contd.)
Method of characteristics (Contd.)
Method of characteristics ( Contd.)
101105024
Aerospace Engineering
High Speed Aero Dynamics
Dr. K.P. Sinhamahapatra
Video
IIT Kharagpur
Select
Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
Lecture-27
Lecture-28
Lecture-29
Lecture-30
Lecture-31
Lecture-32
Lecture-33
Lecture-34
Lecture-35
Lecture-36
Lecture-37
Lecture-38
Lecture-39
Lecture-40
101105030
Aerospace Engineering
Space Flight Mechanics
Dr. Manoranjan Sinha
Video
IIT Kharagpur
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Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
Lecture-27
Lecture-28
Lecture-29
Lecture-30
Lecture-31
Lecture-32
Lecture-33
Lecture-34
Lecture-35
Lecture-36
Lecture-37
Lecture-38
Lecture-39
Lecture-40
Lecture-41
Lecture-42
Lecture-43
Lecture-44
Lecture-45
101105059
Aerospace Engineering
Introduction to Aerodynamics
Dr. K.P. Sinhamahapatra
Video
IIT Kharagpur
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Aircraft and Aerodynamic Forces and Moments
Aircraft and Aerodynamic Forces and Moments (Contd.)
Fluids and Forces in Fluids
Fluids and Forces in Fluids (Contd.)
Forces in Fluids
Forces in Fluids (Contd.)
Kinematics of fluid motion
Kinematics of fluid motion (Contd.)
Kinematics of fluid motion (Contd. )
Kinematics of fluid motion ( Contd.)
Kinematics of fluid motion - Velocity with specified extension and vorticity
Kinematics of fluid motion - Velocity with specified extension and vorticity (Contd.)
Kinematics of fluid motion - Vorticity Distribution
Kinematics of fluid motion - Velocity without expansion and vorticity
Irrotational Solenoidal Flow in Multiply Connected region
Irrotational Solenoidal Flow in Multiply Connected region (Contd.)
Equations of Fluid Motion - Navier - Stokes Equation
Equations of Fluid Motion - Navier - Stokes Equation (Contd.)
Equations of Fluid Motion - Navier - Stokes Equation (Contd. )
Conservation of Energy and Energy Equation
Equations of Motions
Equations of Motion (Contd.)
Exact Solution for Simple Problems
Exact Solution for Simple Problems (Contd.)
Non-dimensional Form of the Equations and Possible Simplifications
High Reynolds Number Approximation
Conditions fior Incompressibility
Potential Flow
Potential Flow - Combination of Basic Solutions
Potential Flow - Combination of Basic Solutions (Contd.)
Potential Flow - Combination of Basic Solutions (Contd. )
Potential Flow - Combination of Basic Solutions (Contd. ) - Lifting Cylinder
Conformal Transformation
Conformal Transformation (Contd.)
Zhukovsky Transformation
Zhukovsky Transformation (Contd.)
Zhukovsky Transformation - Applications
Zhukovsky Transformation - Applications (Contd.)
Zhukovsky Transformation - Applications (Contd. )
Transformation
Transformation (Contd.)
Boundary - Layer Theory
Boundary - Layer Theory (Contd.)
Boundary - Layer Theory (Contd. )
Boundary - Layer Theory ( Contd)
Boundary - Layer Theory ( Contd. )
101106031
Aerospace Engineering
Acoustic Instabilities in Aerospace Propulsion
Prof. R.I. Sujith
Video
IIT Madras
Select
Lecture 1 : Introduction to Thermoacoustic Instabilities
Lecture 2 : Part I : Introduction to Acoustics Part II : Conservation Equations
Lecture 3 : Wave Equation and its Solution in Time Domain
Lecture 4 : Part I : Harmonic Waves Part II : Acoustic Energy Corollory
Lecture 5 : Standing Waves
Lecture 6 : Standing Waves - 2
Lecture 7 : Power Flow and Acoustic Admittance
Lecture 8 : Impedance Tube Technique
Lecture 9 : Admittance and Standing Waves
Lecture 10 : Admittance,Stability and Attenuation
Lecture 11 : Attenuation : Continued Sound Propagation Through Inhomogeneous Media - 1
Lecture 12 : Sound Propagation Through Inhomogeneous Media - 2
Lecture 13 : Sound Propagation Through Inhomogeneous Media - 3
Lecture 14 : Multidimensional Acoustic Fields - 1
Lecture 15 : Multidimensional Acoustic Fields - 2
Lecture 16 : Interaction between Sound and Combustion
Lecture 17 : Reference Books Derivation of Rayleigh Criteria
Lecture 18 : Effect of Heat release on the Acoustic Field
Lecture 19 : Modal Analysis of Thermoacoustic Instability - 1
Lecture 20 : Modal Analysis of Thermoacoustic Instability - 2
Lecture 21 : Active Control of Thermoacoustic Instability
Lecture 22 : Toy model for a Rijke tube in Time Domain
Lecture 23 : Galerkin Technique for Thermoacoustics
Lecture 24 : Evolution Equation for Thermoacoustics
Lecture 25 : Non linear analysis of Thermoacoustic Instability
Lecture 26 : Non-normality, Transient Growth and Triggering Instability – 1
Lecture 27 : Non-normality, Transient Growth and Triggering Instability - 2
Lecture 28 : Non-normality, Transient Growth and Triggering Instability - 3
Lecture 29 : Bifurcations
Lecture 30 : Premixed Flame Acoustic Interaction - 1
Lecture 31 : Premixed Flame Acoustic Interaction - 2
Lecture 32 : Combustion instability due to Equivalence Ratio Fluctuation
Lecture 33 : Role of Hydrodynamic Instabilities - 1
Lecture 34 : Role of Hydrodynamic Instabilities - 2
Lecture 35 : Role of Hydrodynamic Instabilities - 3
Lecture 36 : Active Control of Thermoacoustic Instability Revisited
Lecture 37 : Solid Propellant Combustion Instability - 1
Lecture 38 : Solid Propellant Combustion Instability - 2
Lecture 39 : Response of a Diffusion Flame to Acoustic Oscillations -1
Lecture 40 : Response of a Diffusion Flame to Acoustic Oscillations - 2
Lecture 41 : Response of a Diffusion Flame to Acoustic Oscillations – 3
101106033
Aerospace Engineering
Aerospace Propulsion
Dr. P.A. Ramakrishna
Video
IIT Madras
Select
Introduction
Air breathing Engines � Turbojet I
Air breathing Engines � Turbojet II
Air breathing Engines � Turboprop & Turbofan
Air breathing Engines � Ramjet & Scramjet
Non-air breathing Engines I
Non-air breathing Engines II
General Performance Parameters I
General Performance Parameters II
Cycle Analysis � Ramjet
Cycle Analysis � Turbojet I
Cycle Analysis � Turbojet II
Cycle Analysis � Turbojet III
Cycle Analysis � Turbojet IV
Cycle Analysis � Turbojet V
Cycle Analysis � Turbojet VI
Cycle Analysis � Turbofan
Rocket Nozzles � 1D Analysis I
Rocket Nozzles � 1D Analysis II
Rocket Nozzles � 1D Analysis III
Rocket Nozzles � Real Effects I
Rocket Nozzles � Real Effects II
Rocket Nozzles � Thrust Vectoring
Solid Rockets � Propellants
Solid Rockets � Burn rate
Solid Rockets � Performance
Solid Rockets � Grain
Solid Rockets � Ignition, Quenching
Solid Rockets � Igniter, Depressurization
Propellant Combustion � Combustion Modelling
Liquid Rocket � Propellants
Liquid Rocket � Nozzle Cooling I
Liquid Rocket � Nozzle Cooling II
Liquid Rocket � Nozzle Cooling III
Liquid Rocket � Pressure fed system
Liquid Rocket � Pump fed system
Liquid Rocket � Pumps
Liquid Rocket � Fuel Injection
Hybrid Rocket � Basics
Hybrid Rocket Performance
Hybrid Rocket Combustion
Chemical Equilibrium Analyser � SP 273
101106035
Aerospace Engineering
Airplane design (Aerodynamic)
Prof. E.G. Tulapurkara
Web
IIT Madras
Select
Introduction 1 - Lecture 1
Introduction - 2 Lecture 2
Introduction - 3 Lecture 3
Chapter 1 - References
Chapter 1 - Exercises
Data collection and preliminary three-view drawing - 1 Lecture 4
Data collection and preliminary three-view drawing - 2 Lecture 5
Chapter 2 - Exercises
Weight estimation - 1 Lecture 6
Weight estimation - 2 Lecture 7
Weight estimation - 3 Lecture 8
Chapter 3 - References
Chapter 3 - Exercises
Estimation of wing loading and thrust loading - 1 Lecture 9
Estimation of wing loading and thrust loading - 2 Lecture 10
Estimation of wing loading and thrust loading - 3 Lecture 11
Estimation of wing loading and thrust loading - 4 Lecture 12
Estimation of wing loading and thrust loading - 5 Lecture 13
Estimation of wing loading and thrust loading - 6 Lecture 14
Estimation of wing loading and thrust loading - 7 Lecture 15
Estimation of wing loading and thrust loading - 8 Lecture 16
Estimation of wing loading and thrust loading - 9 Lecture 17
Estimation of wing loading and thrust loading -10 Lecture 18
Chapter 4 - References
Chapter 4 - Exercises
Wing design - selection of wing parameters - 1 Lecture 19
Wing design - selection of wing parameters - 2 Lecture 20
Wing design - selection of wing parameters - 3 Lecture 21
Wing design - selection of wing parameters - 4 Lecture 22
Chapter 5 - References
Chapter 5 - Exercises
Fuselage and tail sizing - 1 Lecture 23
Fuselage and tail sizing - 2 Lecture 24
Fuselage and tail sizing - 3 Lecture 25
Fuselage and tail sizing - 4 Lecture 26
Fuselage and tail sizing - 5 Lecture 27
Fuselage and tail sizing - 6 Lecture 28
Fuselage and tail sizing - 7 Lecture 29
Fuselage and tail sizing - 8 Lecture 30
Chapter 6 Exercises
Special considerations in configuration layout Lecture 31
Chapter 7 References
Chapter 7 - Exercises
Weights and centre of gravity - 1 Lecture 32
Weights and centre of gravity - 2 Lecture 33
Chapter 8 - Exercises
Cross-checks on design of tail surfaces - 1 Lecture 34
Cross-checks on design of tail surfaces -2 Lecture 35
Cross-checks on design of tail surfaces - 3 Lecture 36
Cross-checks on design of tail surfaces - 4 Lecture 37
Chapter 9 - References
Chapter 9 - Exercises
Miscellaneous topics - 1 Lecture 38
Miscellaneous topics -2 Lecture 39
Miscellaneous topics - 3 Lecture 40
Chapter 10 - Exercises
Appendix 10.2 - Self study
101106038
Aerospace Engineering
Composite Materials
Prof. R. Velmurugan
Web
IIT Madras
Select
Introduction
Applications
Classifications
Manufacturing techniques
Micro mechanics of Lamina
Macro mechanics of Lamina and problems
Macro mechanics of laminate
Classical lamination theory
Inter laminar stresses
Failure theories and problems
101106040
Aerospace Engineering
Experimental Gas/Aerodynamics
Prof. Job Kurian
Web
IIT Madras
Select
Wind tunnels
High Speed Wind Tunnels
Shock Tube
Hypersonic Facilities
Measurement of Pressure
Measurement of temperature
Velocity measurements
Flow Visualisation
101106041
Aerospace Engineering
Flight dynamics I - Airplane performance
Prof. E.G. Tulapurkara
Web
IIT Madras
Select
Introduction - 1 Lecture 1
Introduction - 2 Lecture 2
introduction - 3 Lecture 3
Earth's Atmosphere -1 Lecture 4
Earth's Atmosphere - 2 Lecture 5
Chapter 1 - References
Chapter 1 - Exercises
Drag polar - 1 Lecture 6
Chapter 2 - References
Chapter 2 - Exercises
Chapter 2 - Table 2.1
Drag polar - 2 Lecture 7
Drag polar - 3 Lecture 8
Drag polar - 4 Lecture 9
Drag polar - 5 Lecture 10
Drag polar - 6 Lecture 11
Drag polar - 7 Lecture 12
Chapter 3 - References
Chapter 3 - Exercises
Engine characteristics - 1 Lecture 13
Engine characteristics - 2 Lecture 14
Engine characteristics - 3 Lecture 15
Engine characteristics - 4 Lecture 16
Chapter 4 - References
Chapter 4 - Exercises
Steady level flight - 1 Lecture 17
Steady level flight - 2 Lecture 18
Steady level flight - 3 Lecture 19
Steady level flight - 4 Lecture 20
Chapter 5 - References
Chapter 5 - Exercises
Steady climb, descent and glide - 1 Lecture 21
Steady climb, descent and glide - 2 Lecture 22
Steady climb, descent and glide - 3 Lecture 23
Chapter 6 - Exercises
Range and endurance - 1 Lecture 24
Range and endurance - 2 Lecture 25
Range and endurance - 3 Lecture 26
Chapter 7 - Reference
Chapter 7 - Exercises
Accelerated level flight and climb Lecture 27
Chapter 8 - Exercise
Manoeuvres - 1 Lecture 28
Manoeuvres - 2 Lecture 29
Manoeuvres - 3 Lecture 30
Manoeuvres - 4 Lecture 31
Chapter 9 - Exercises
Take-off and landing - 1 Lecture 32
Take-off and landing - 2 Lecture 33
Take-off and landing - 3 Lecture 34
Chapter 10 - References
Chapter 10 - Exercises
Appendix - A - 1 Lecture 35
Appendix - A - 2 Lecture 36
Appendix - A - 3 Lecture 37
Appendix - A - References
Appendix - B - 1 Lecture 38
Appendix - B - 2 Lecture 39
Appendix - B - 3 Lecture 40
Appendix - B - References
101106042
Aerospace Engineering
Flight Dynamics II (Stability)
Dr. Nandan Kumar Sinha
Video
IIT Madras
Select
Lecture 1 : Earth Atmosphere, Aircraft components, Aircraft nomenclature
Lecture 2 : Basic aerodynamics
Lecture 3 : Equilibrium and stability
Lecture 4 : Static vs dynamic stability
Lecture 5 : Criterion for stability, Wing contribution
Lecture 6 : Horizontal tail contribution
Lecture 7 : Wing plus tail contribution
Lecture 8 : Static margin and CG limits
Lecture 9 : Fuselage contribution
Lecture 10 : Powerplant contribution
Lecture 11 : Power effects on neutral point
Lecture 12 : Elevator
Lecture 13 : Stick free stability, Most fwd CG location
Lecture 14 : Longitudinal stick force per 'g', Ground effect
Lecture 15 : Control requirement, Pull-up maneuver,Maneuver point
Lecture 16 : Elevator per 'g' , Maneuver point
Lecture 17 : Example problems
Lecture 18 : Lateral-Directional Stability Derivatives, Fuselage/Vertical fin contribution
Lecture 19 : Roll stability, Wing sweep effect, Rudder
Lecture 20 : Dihedral effect, Various contributions
Lecture 21 : Power effects, Roll control, Aileron
Lecture 22 : Example problems
Lecture 23 : Derivation of Translational Motion Equations
Lecture 24 : Derivation of Angular Motion Equations
Lecture 25 : Description of various forces and moments
Lecture 26 : Nonlinearities and Associated Aircraft Behavior
Lecture 27 : Small perturbation method, Linearization of equations
Lecture 28 : Aerodynamic force and Moment Derivatives
Lecture 29 : Contribution of Aircraft components to Aerodynamic Derivatives
Lecture 30 : Linear Model and Aircraft Dynamics Modes
Lecture 31 : Short Period, Phugoid(Lanchester's formulation)
Lecture 32 : Short period mode approximation
Lecture 33 : Flying and Handling Qualities, Cooper Harper Scale
Lecture 34 : Pure rolling motion, Pure yawing motion,Spiral approximation
Lecture 35 : Spiral, Roll, Dutch roll Mode approximations
Lecture 36 : Lateral directional Flying Qualities, Routh's Stability criterion
Lecture 37 : Stability in Steady Roll Maneuver
Lecture 38 : Wind Effect on Aircraft Pure Plunging Motion
Lecture 39 : Wind Profiles, Longitudinal Mode Response to Wind Shear
Lecture 40 : Stability control/Augmentation
Lecture 41 : Autopilots, Automatic Landing System
101106043
Aerospace Engineering
Flight dynamics II - Airplane stability and control
Prof. E.G. Tulapurkara
Web
IIT Madras
Select
Introduction-1 Lecture 1
Introduction-2 Lecture 2
Introduction-3 Lecture 3
Chapter 1 - References
Chapter 1 - Exercises
Longitudinal stick-fixed static stability and control - 1 Lecture 4
Longitudinal stick-fixed static stability and control-2 Lecture 5
Longitudinal stick-fixed static stability and control-3 Lecture 6
Longitudinal stick-fixed static stability and control-3 Lecture 7
Longitudinal stick-fixed static stability and control-5 Lecture 8
Longitudinal stick-fixed static stability and control-6 Lecture 9
Longitudinal stick-fixed static stability and control-7 Lecture 10
Longitudinal stick-fixed static stability and control-8 Lecture 11
Chapter 2 - References
Chapter 2 - Exercises
Longitudinal stick-free static stability and control-1 Lecture 12
Longitudinal stick-free static stability and control-2 Lecture 13
Longitudinal stick-free static stability and control-3 Lecture 14
Chapter 3 - References
Chapter 3 - Exercises
Longitudinal static stability and control-effect of acceleration - 1 Lecture 15
Chapter 4 - Exercises
Directional static stability and control-1 Lecture 16
Directional static stability and control-2 Lecture 17
Directional static stability and control-3 Lecture 18
Chapter 5 - Exercises
Lateral static stability and control - 1 Lecture 19
Lateral static stability and control - 2 Lecture 20
Lateral static stability and control - 3 Lecture 21
Chapter 6 - References
Chapter 6 - Exercises
Dynamic stability analysis -I-Equations of motion and estimation of stability derivatives -1 Lecture 22
Dynamic stability analysis-I-Equations of motion and estimation of stability derivatives-2 Lecture 23
Dynamic stability analysis-I-Equations of motion and estimation of stability derivatives-3 Lecture 24
Dynamic stability analysis-I-Equations of motion and estimation of stability derivatives-4 Lecture 25
Dynamic stability analysis-I-Equations of motion and estimation of stability derivatives-5 Lecture 26
Dynamic stability analysis-I-Equations of motion and estimation of stability derivatives-6 Lecture 27
Chapter 7 - References
Chapter 7 - Exercises
Dynamic stability analysis - II - Longitudinal motion - 1 Lecture 28
Dynamic stability analysis-II-Longitudinal motion - 2 Lecture 29
Dynamic stability analysis-II-Longitudinal motion - 3 Lecture 30
Dynamic stability analysis-II-Longitudinal motion - 4 Lecture 31
Dynamic stability analysis-II-Longitudinal motion - 5 Lecture 32
Chapter 8 - References
Chapter 8 - Exercises
Dynamic stability analysis-III-lateral motion-1 Lecture 33
Dynamic stability analysis-III-lateral motion - 2 Lecture 34
Chapter 9 - Reference
Chapter 9 - Exercises
Miscellaneous topics - 1 Lecture 35
Miscellaneous topics - 2 Lecture 36
Chapter 10 - References
Chapter 10 - Exercises
Appendix - C - 1 Lecture 37
Appendix - C - 2 Lecture 38
Appendix - C - 3 Lecture 39
Appendix - C - 4 Lecture 40
Appendix - C - References
samphtm question paper and hints for solution
samphtm question paper - model answers
101106044
Aerospace Engineering
Gas Dynamics
Dr. T.M. Muruganandam
Video
IIT Madras
Select
Lecture 01
Lecture 02
Lecture 03
Lecture 04
Lecture 05
Lecture 06
Lecture 07
Lecture 08
Lecture 09
Lecture 10
Lecture 11
Lecture 12
Lecture 13
Lecture 14
Lecture 15
Lecture 16
Lecture 17
Lecture 18
Lecture 19
Lecture 20
Lecture 21
Lecture 22
Lecture 23
Lecture 24
Lecture 25
Lecture 26
Lecture 27
Lecture 28
Lecture 29
Lecture 30
Lecture 31
Lecture 32
Lecture 33
Lecture 34
Lecture 35
Lecture 36
Lecture 37
Lecture 38
Lecture 39
Lecture 40
Lecture 41
Lecture 42
Lecture 43
Lecture 44
Lecture 45
Lecture 46
Lecture 47
Lecture 48
Lecture 49
Lecture 50
Lecture 51
Lecture 52
Lecture 53
Lecture 54
101106045
Aerospace Engineering
Introduction to CFD
Prof. M. Ramakrishna
Video
IIT Madras
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Introduction, Why and how we need computers
Representing Arrays and functions on computers
Representing functions - Box functions
Representing functions - Polynomials & Hat functions
Hat functions, Quadratic & Cubic representations
Demo - Hat functions, Aliasing
Representing Derivatives - finite differences
Finite differences, Laplace equation
Laplace equation - Jacobi iterations
Laplace equation - Iteration matrices
Laplace equation - convergence rate
Laplace equation - convergence rate Continued
Demo - representation error, Laplace equation
Demo - Laplace equation, SOR
Laplace equation - final, Linear Wave equation
Linear wave equation - Closed form & numerical solution, stability analysis
Generating a stable scheme & Boundary conditions
Modified equation
Effect of higher derivative terms on Wave equation
Artificial dissipation, upwinding, generating schemes
Demo - Modified equation, Wave equation
Demo - Wave equation / Heat Equation
Quasi-linear One-Dimensional. wave equation
Shock speed, stability analysis, Derive Governing equations
One-Dimensional Euler equations - Attempts to decouple
Derive Eigenvectors, Writing Programs
Applying Boundary conditions
Implicit Boundary conditions
Flux Vector Splitting, setup froms averaging
Roes averaging
Demo - One Dimensional flow
Accelerating convergence - Preconditioning, dual time stepping
Accelerating convergence, Intro to Multigrid method
Multigrid method
Multigrid method - final, Parallel Computing
Calculus of Variations - Three Lemmas and a Theorem
Calculus of Variations - Application to Laplace Equation
Calculus of Variations -final & Random Walk
Overview and Recap of the course
101106046
Aerospace Engineering
Space Technology
Dr. Nandan Kumar Sinha, Dr. Amit Kumar
Web
IIT Madras
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Review of fluid mechanics
Thrust from stationary rocket engine/motor, specific impulse
Rocket vehicle acceleration, the rocket equation in free space
Effect of gravity and atmospheric drag
Ascent phase and trajectories
Chemical rockets and multi-staging
Limit of multi-staging, optimal staging with identical stages
Optimal staging with non-identical stages
Parallel staging
Electrical propulsion
Optimal payload in an electrical rocket
Fundamentals of orbital mechanics
Equation of motion for the two body problem
Elliptic trajectories
Parabolic and hyperbolic trajectories
Orbital maneuvers in Earth-satellite system
Orbital maneuvers in deep space missions
Low thrust missions
Atmosphere, radiation and magnetic fields, space mission types
Introduction, re-entry types
Re-entry dynamics for ballistic re-entry
Re-entry heating
Introduction to Spacecraft Attitude Dynamics; Space Environment, Satellite subsystems
Spherical Geometry, Various Axes Systems
Attitude Dynamics
Attitude Determination Techniques
Attitude Stabilization and Control
101108047
Aerospace Engineering
Advanced Control System Design for Aerospace Vehicles
Dr. Radhakant Padhi
Video
IISc Bangalore
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Introduction and Motivation for Advanced Control Design
Classical Control Overview - I
Classical Control Overview - II
Classical Control Overview - III
Classical Control Overview � IV
Basic Principles of Atmospheric Flight Mechanics
Overview of Flight Dynamics - I
Overview of Flight Dynamics � II
Representation of Dynamical Systems � I
Representation of Dynamical Systems � II
Representation of Dynamical Systems � III
Review of Matrix Theory - I
Review of Matrix Theory - II
Review of Matrix Theory - III
Review of Numerical Methods
Linearization of Nonlinear Systems
First and Second Order Linear Differential Equations
Time Response of Linear Dynamical Systems
Stability of Linear Time Invariant Systems
Controllability and Observability of linear Time Invariant Systems
Pole Placement Control Design
Pole Placement Observer Design
Static Optimization: An Overview
Calculus of Variations: An Overview
Optimal Control Formulation using Calculus of Variations
Classical Numerical Methods for Optimal Control
Linear Quadratic Regulator (LQR) Design - 1
Linear Quadratic Regulator (LQR) Design - 2
Linear Control Design Techniques in Aircraft Control � I
Linear Control Design Techniques in Aircraft Control � II
Lyapunov Theory � I
Lyapunov Theory � II
Constructions of Lyapunov Functions
Dynamic Inversion � I
Dynamic Inversion � II
Neuro-Adaptive Design � I
Neuro-Adaptive Design � II
Neuro-Adaptive Design for Flight Control
Integrator Back-Stepping; Linear Quadratic (lQ) Observer
An Overview of Kalman Filter Theory
101108054
Aerospace Engineering
Guidance of Missiles
Prof. Debasish Ghose
Web
IISc Bangalore
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Foreword
What is Guidance?
History of Guided Missiles
Airframe
Flight Control System
Guidance Subsystem
Proximity Fuze; Propulsion System; Warhead
Guidance Phases During Missile Flight; Categories of Homing Guidance
Standard Terminologies in Missile Guidance
Engagement between Two Point Objects
Collision Condition and Collision Triangle
An Overview of Guidance Laws
Conceptual Classical Guidance Laws
Implementable Classical Guidance Laws
Modern Guidance Laws
Pure Pursuit Guidance Law
Time of Interception; Miss-Distance
Deviated Pursuit Guidance Law
The Capture Region; Implementation
Introduction; LOS Guidance
Implementation of LOS Guidance; CLOS; BR
Some Additional Analysis
PPN; TPN; GTPN; IPN
Original TPN with Non-maneuvering Target
Realistic True Proportional Navigation
Comparison of TPN Guidance Laws
Miss-distance Analysis for RTPN
Introduction; Non-maneuvering Target
Non-Maneuvering Target (Contd..)
An Illustrative Example
Maneuvering Target
Maneuvering Target (Contd..)
Missile Latax
Representation of PPN capturability in the relative velocity space
PN Based Impact Angle Constrained Guidance
Composite Guidance Law
Impact Angles Against a Moving Target with Proportional Navigation
The Proposed Guidance Law
Linearized Proportional Navigation
Comparison between PN and APN
Optimal Control Guidance Laws
101108056
Aerospace Engineering
Navigation, Guidance, And Control
Prof. Debasish Ghose
Web
IISc Bangalore
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Foreword
Introduction
Principles of Radars
Radar Block Diagram and Operation
Doppler Effect; CW Radars
Applications; FM-CW Radars
MTI and Pulse Doppler Radars
Introduction; Classification; Description
Guidance Phases; Categories; Useful Concepts
Classification; Classical Guidance Laws
Modern Guidance Laws
Introduction; Types of Navigation; LORAN System
DECCA; OMEGA; VOR; INS; Integrated Systems
Basic Definitions; Open Loop and Closed Loop Systems
Linearity; Causality
Laplace Transforms
Input-Output Description; Performance Criteria
Transfer Function; Initial and Final Value Theorem; Partial Fraction Expansion
Time Response; First Order Systems
Second Order Systems
Performance of Second Order Systems
Higher Order Systems; Block Diagram Algebra
Stability; Hurwitz Determinants; Routh-Hurwitz Criterion
Special Cases and Applications of Routh-Hurwitz Criterion
Feedback Control; P-Control
Steady State Error; Disturbance Signals
Root Locus; Evan�s Form
Complex Variables; Angle Criterion
Steps to Obtain Root Locus
Root Locus Example
Controller Design using Root Locus; PD-Control; Lead Control
PI-Control; Lag Control; Aircraft Example
Compensator Design using Root Locus
Response to Sinusoidal Input; Frequency Response Plots
Bode Plots of Simple Functions
Bode Plots of Complex Functions
Nyquist Plots
Applications of Nyquist Plots
Gain and Phase Margins
State Equations; State Transition Matrix and Equations
Relation with Transfer Functions; Controllability and Observability
101108057
Aerospace Engineering
Optimal Control, Guidance and Estimation.
Dr. Radhakant Padhi
Video
IISc Bangalore
Select
Introduction, Motivation and Overview
Overview of SS Approach and Matrix Theory
Review of Numerical Methods
An Overview of Static Optimization � I
An Overview of Static Optimization � II
Review of Calculus of Variations � I
Review of Calculus of Variations � II
Optimal Control Formulation Using Calculus of Variations
Classical Numerical Methods to Solve Optimal Control Problems
Linear Quadratic Regulator (LQR) � I
Linear Quadratic Regulator (LQR) � II
Linear Quadratic Regulator (LQR) � III
Linear Quadratic Regulator (LQR) � III
Discrete-time Optimal Control
Overview of Flight Dynamics � I
Overview of Flight Dynamics � II
Overview of Flight Dynamics � III
Linear Optimal Missile Guidance using LQR
SDRE and θ - D Designs
Dynamic Programming
Approximate Dynamic Programming (ADP), Adaptive Critic (AC) and Single Network Adaptive Critic (SNAC) Design
Transcription Method to Solve Optimal Control Problems
Model Predictive Static Programming (MPSP) and Optimal Guidance of Aerospace Vehicles
MPSP for Optimal Missile Guidance
Model Predictive Spread Control (MPSC) and Generalized MPSP (G-MPSP) Designs
Linear Quadratic Observer & An Overview of State Estimation
Review of Probability Theory and Random Variables
Kalman Filter Design � I
Kalman Filter Design � II
Kalman Filter Design � III
Integrated Estimation, Guidance & Control � I
Integrated Estimation, Guidance & Control � II
LQG Design; Neighboring Optimal Control & Sufficiency Condition
Constrained Optimal Control � I
Constrained Optimal Control � II
Constrained Optimal Control � III
Optimal Control of Distributed Parameter Systems � I
Optimal Control of Distributed Parameter Systems � II
Take Home Material: Summary � I
Take Home Material: Summary � II
101104018
Aerospace Engineering
Introduction to Propulsion
Dr. D.P. Mishra
Video
IIT Kanpur
Select
Lecture-01
Lecture-02
Lecture-03
Lecture-04
Lecture-05
Lecture-06
Lecture-07
Lecture-08
Lecture-09
Lecture-10
Lecture-11
Lecture-12
Lecture-13
Lecture-14
Lecture-15
Lecture-16
Lecture-17
Lecture-18
Lecture-19
Lecture-20
Lecture-21
Lecture-22
Lecture-23
Lecture-24
Lecture-25
Lecture-26
Lecture-27
Lecture-28
Lecture-29
Lecture-30
Lecture-31
Lecture-32
Lecture-33
Lecture-34
Lecture-35
Lecture-36
Lecture-37
Lecture-38
Lecture-39
Lecture-40
119106008
Aerospace Engineering
Introduction to Atmospheric Science
Prof. C. Balaji
Video
IIT Madras
Select
Introduction
Atmosphere-A brief survey (Pressure, Temperature and Chemical composition)
Atmosphere-A brief survey contd … (Vertical structure of the atmosphere)
Vertical structure of atmosphere contd ... and The Earth system - Oceans
The Earth system – Oceans Contd... and Marine biosphere
The Earth system – Hydrological cycle
The Earth system – Hydrological cycle contd ... and Carbon cycle
The Earth system – Carbon cycle contd..., and Carbon in the oceans Earth's crust
The Earth system -- Carbon in the oceans Earth's crust
Atmospheric Thermodynamics- Introduction
The hydrostatic equation
Hypsometric equation and pressure at sea level
Basic Thermodynamics
Concept of air parcel and dry adiabatic lapse rate
Potential temperature
Skew-T ln-P chart
Problems using Skew-T ln-P chart
Problems using Skew-T ln-P chart.
Problems using Skew-T ln-P chart..
Lifting Condensation Level (LCL)
Lifting condensation level Contd...
Saturated Adiabatic and Psuedo-adiabatic processes
Equivalent potential temperature and wet bulb potential temperature
Normand's rule - Chinook winds
Problems on Chinook wind and static stability
Static stability-Brunt-Visala frequency
Conditional and convective instability
Static stability - Problems using radiosonde data and skew T ln P chart
The second law of thermodynamics – Clausius Clapeyron relation
Clausius Clapeyron relation contd..
Atmospheric radiation – Radiation laws
Planck's distribution and Inverse square law
Physics of scattering, emmision and absorption
Physics of scattering, emmision and absorption contd...
Radiative Transfer Equation – Derivation
Radiative Transfer Equation contd..
Radiative heating profiles of the atmosphere
Climate Dynamics – Introduction
Climate sensitivity and feedback
Climate change
Atmospheric dynamics
101104061
Aerospace Engineering
NOC:Introduction to airplane performance
Dr. A.K. Ghosh
Video
IIT Kanpur
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General Introduction: Airplane Performance Characteristics
George Cayley: Concept of Lift and Drag
Introduction to airplane and its components
Hansa 3 Aircraft and its Primary Systems
Concept of Lift Aerofoil: Wing : Complete Aircraft
Drag Polar
Revision
Standard Atmosphere: Description and Modeling
Measuring Instruments: Altimeter, Airspeed Indicator
Equations of Motion: Static Performance
Thrust Required, Power Required: Cruise
Excess Thrust and Power: Climb Angle and Rate of Climb
Review
Thrust Required: A Closer Look
Modeling of CL: Dimensional Analysis
A Closer Look: Point Mass Model, Dimensional Analysis
Estimation of Drag Polar Through Flight Test
Estimation of Rate of Climb
Revision.
Range and Endurance
Range and Endurance: Continued...
Gliding Flight
Accelerated Flight
V-n Diagram
Revision..
V stall: Cruise and Manoeuvre
Flaps:High Lift Devices to Reduce Take off / Landing Distance
Take off: Warm-up Lecture
Take off Performance
Take off Performance:Continued...
Revision...
Landing Performance
Landing Performance: Continued...
Challanges in Takeoff and Landing: Single and Twin Engines
Introduction to Static Stability
Positioning of Center of Pressure for Static Stability
Revision.....
Stability and Control: Designers Perspective
Stability and Control: Designers Perspective Continued...
Longitudinal Control: Elevator
Contribution of Wing and Tail: Stability
Stability: Wing and Tail Contribution
Control: Elevator
Control: Delta-e Required
Control: Delta-e Required continued...
Design Basics: Wing Loading & Thrust Loading
Design Basics: Sweep & Dihedral
Revision .