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Package Includes

  • Aerodynamics
    • Previous Year Questions (PYQs)
      • PYQs | Aerodynamics
    • Basic Aerodynamics
      • Lecture-1 | Introduction | Discussion | Basic Concepts | Road map
      • Lecture-2 | Overview | Types of flow | Bernoulli's EQN | Pressure Coefficient
      • Lecture-3 | Bernoulli's & Continuity Eqn | Discussion | Low speed Aerodynamics
      • Lecture-4 | Energy Equation | Total properties | Low speed wind tunnel & Venturi-meter
      • Lecture-5 | Pressure coefficient| max value in incompressible & Compressible flow| Numerical |PYQs
      • Lecture-6 | Pressure distribution | Cp vs (X/c) | Variation of pressure coefficient with incidence
      • Lecture-7 | Airspeed Indicator | Types of Airspeeds and errors | PYQs Discussion
      • Lecture-8 | Airspeed Indicator | TAS,EAS,IAS,CAS| Numerical | PYQs
    • Thin Airfoil Theory & High Lift Devices
      • Lecture-1 | Airfoil Nomenclature | Concept of Positive, Negative and Zero Camber & Lift Curve Slope | Discussion
      • Lecture-2 |NACA Series| NACA 4 & 5 digit Series |High, Low & Infinite Aspect Ratio Wing | Discussion
      • Lecture-3| Revision | NACA Series | PYQs
      • Lecture-4| Lift Curve Slope | Effect of camber on (Cl)max , stalling angle & zero lift incidence or angle of attack
      • Lecture-5|Thin Airfoil Theory Results |Aerodynamic Center & its location| Pitching moment at various point along the chord
      • Lecture-6| Center of Pressure| its Location & properties | Numerical | Homework
      • Lecture-7| Practice Questions | PYQs Thin Airfoil Theory | must watch
    • Prandtl- Glauert Theory & Supersonic Linearized Theory
      • Lecture-1 | Supersonic Linearized Theory | Prandtl-Glauert Rule | Numerical | PYQs
      • Lecture-2 | Critical Mach Number | Critical Pressure | Drag Divergence Mach number
      • Lecture-3 | Prandtl Glauert Rule | Transonic Aerodynamics | PYQs
    • Finite Wing Theory
      • Lecture-1 | Finite Wing Theory | Downwash & Wing tip vortices | Induced angle of attack
      • Lecture-2 | Induced Drag | Methods to reduce Induced Drag
      • Lecture-3 | Helmholtz Theorems | Kelvin's Circulation Theorem | Wing Tip Vortices
      • Lecture-4| Induced Velocity at a point due to Vortex Filament | Numerica
      • Lecture-5 | Numerical | Induced Velocity | Horse-shoe Vortex
      • Lecture-6| Lifting Line Theory
      • Lecture-7 | Elliptical Lift Distribution | Numerical
      • Lecture-8 | Numerical | PYQs | Elliptical & Lifting Line Theory
      • Lecture-9 | Geometric Features of Finite Wing or 3D Wing
      • Lecture-10 | Cruise Flight | Cruise speed | Stalling Speed
      • Lecture-11| Calculation of Lift Coefficient and Lift Slope of 3D Wing |Numerical | PYQs
  • Fluid Mechanics
    • Previous Year Questions (PYQs)
      • PYQs | Fluid Mechanics
    • Properties of Fluids
      • ISRO
      • Lecture-1| Introduction | Syllabus
      • Lecture- 2 | Fluid Properties
      • Lecture-3 | Viscosity | Effect of temperature & Pressure Viscosity
      • Lecture-4 | Numerical | PYQs
    • Fluid Kinematics & Fluid Dynamics
      • Lecture-1 | Overview | Discussion | Syllabus | Numerical
      • Lecture-2| Eulerian & Lagrangian Approach | Local, Substantial & Material Acceleration | Numerical
      • Lecture-3 | Equation of Stream line | Rotational & Irrotational Flow | Vorticity | Circulation | Numerical
      • Lecture-4 | Numerical | Stream Line, Path Line & Streak Line | PYQs
      • Lecture-5| Potential Function, Stream Function & relation between them | Numerical | PYQs
      • Lecture-6 | Circulation | Numerical | Free-Vortex Flow |Singularity | PYQs
    • Potential Flow Theory
      • Lecture-1| Introduction | Potential Flow | Overview | PYQs
      • Lecture-2| Uniform Flow | Source and Sink Flow | Pressure at any point in the source & Sink Flow
      • Lecture-3 | Source Flow |Flow Past a Half Body | |Pressure calculation | Pressure Coefficient| Numerical
      • Lecture-4| Numerical | Flow Past a Half Body or Rankine Half Body| Home Work
      • Lecture-5| Flow Past a Rankine Oval Body| Numerical| Source & Sink Pair| Doublet
  • Engineering Mathematics
    • Previous Year Questions (PYQs)
      • PYQs | Mathematics
    • Calculus
      • Lecture-1 | Definite & Improper Integral
      • Lecture-2 | Maxima and Minima | Multi- Variable
      • Lecture-3| Maxima & Minima | Single Variable | Point of Inflection
      • Lecture-4 | Limit, Continuity & Differentiability
      • Lecture-5 | Limit , Continuity & Differentiability
      • Lecture-6 | Limits & Continuity | L.Hospital Rule
    • Vector Calculus
      • Lecture-1|Introduction | Terminologies in Vector Calculus: Gradient, Divergence & Curl
      • Lecture-2 | Directional Derivative & Unit Normal | Curl & Divergence | Numerical
      • Lecture-3 | Position Vector or Radial vector | Scalar Potential | Numerical
      • Lecture-4 | Questions based on Position vector & some important properties
      • Lecture-5 | Work Done as a scalar product | Vector Integration | Work done as a fn ( path & end points)
      • Lecture-6 | Vector Integration | Work done as a function of End points alone | Independent of Path
      • Lecture-7 | Review of Double & Triple Integral
      • Lecture-8 | Integral Theorems | Green's Theorem
      • Lecture:9 | Gauss-Divergence Theorem | Questions
      • Lecture-10 | Stoke's Theorem | Practice Questions | PYQs
    • Matrix Algebra
      • Lecture : 1 | Introduction | Matrix Algebra
      • Lecture-2 | Subtraction ,Addition and Multiplication of Matrices & their properties
      • Lecture-3 | Inverse of a Matrix | Minor and Cofactor | Determinant & its Properties
      • Lecture-4 | Eigen Values & Eigen Vectors of a Matrix & their Properties
      • Lecture-5 | Eigen values and its properties | Numerical
      • Lecture-6 | Eigen Vectors and its properties | Numerical
      • Lecture-7 | Eigen Vectors | Rank of Matrix | Numerical
      • Lecture-8 |Consistent & Inconsistent Solution |Rouch's Theorem| Homogeneous & Non-Homogeneous EQN
      • Lecture-9 | Numerical | Unique ,Infinite & No solution | Homogeneous & Non- Homogeneous EQNs
      • Lecture-10 | Consistent & Inconsistent Systems | Numerical
      • Lecture-11 | Numerical | Property based Question| Must watch lecture
    • Ordinary Differential Equation
      • Lecture-1:Introduction | Order and Degree of a differential equation
      • Lecture-2 | Higher Order ODE equation and its Solution | Complementary Function
      • Lecture-3 | Finding Particular Integral | its possible forms | General solution
      • Lecture:4 | Particular Integral | Complementary Function | General Solution
      • Lecture-5 | Method of Variation of Parameters
      • Lecture-6 | Euler's Method or Cauchy-Euler Form | Legendre's Form
      • Lecture-7| First Order First Degree Differential Eqn | Linear Differential Eqn | Standard Form
      • Lecture-8| First order Linear Differential Equation | Bernoulli's Form
      • Lecture-9 | First order Differential Equation | Separation of Variables Method
      • Lecture:10 | Partial Differential Equation | Its classification into Hyperbolic, Parabolic & Elliptical
    • Numerical Methods
      • Lecture-1| Numerical Methods | Trapezoidal & Simpson's Rule | Vector Integration PYQs
      • Lecture-2 | Newton-Rapson Method | Practice Questions | PYQs
  • Airplane Performance
    • Previous Year Questions (PYQs)
      • PYQs | Airplane Performance
    • The Atmosphere | International Standard Atmosphere
      • Lecture-1 | Basic Concepts & importance of Atmosphere
      • Lecture-2 | ISA & Layers of Atmosphere | Calculation in Troposphere
      • Lecture-3| Properties in Linearly varying & Constant Temperature (Isothermal) Layers
      • Lecture-4|Numerical|Calculation of Properties in Troposphere & Stratosphere |Tropopause| Lapse Rate
      • Lecture-5| Types of Altitudes and its importance| Geometric, Geopotential & Absolute Altitudes
      • Lecture:6| Relation between Geometric, Geopotential & Absolute Altitudes| Numerical
      • Lecture:7 | Temperature , Pressure & Density Altitudes | Numerical | Home Work
    • Steady Level Flight | Steady Gliding & Steady Climbing
      • Lecture-1| Introduction | Non accelerated Flight | Steady Level Flight| Gliding and Climbing
      • Lecture-2 | Numerical | Total drag in terms of parasite & Induced drag
      • Lecture-3 | Max Range & Endurance in Steady Gliding | Max ROC & AOC in Steady Climbing
      • Lecture-4 | Minimum Drag & Minimum Power Condition | Minimum (D/V) Condition
      • Lecture-5 | Numerical | Min Drag, Min Power & Min (D/V) Condition | Steady Glide
      • Lecture-6 | Numerical | Steady Gliding & Steady Climbing
      • Lecture-7 | Numerical | Maximum & Minimum Speed | Variation of Ta & Tr , Pa & Pr with altitude
      • Lecture-8 | Max Roc | Absolute & Service Ceiling | its Significance | PYQs
    • Range & Endurance in Steady Level Flight /Cruise Flight
      • Lecture-1 | Introduction | Range & Endurance | Types of Range
      • Lecture-2 | Derivation for Range & Endurance | Jet powered & Propeller Driven Airplane
      • Lecture-3 | Numerical | PYQs
    • Turning Flight
      • Lecture-1 | Radius of Turn & Turn Rate | Minimum Turn Rate & Minimum Turn Radius
      • Lecture-2 | Time to turn | Numerical | PYQs
      • Lecture-3 | Pull-up & Pull-down Maneuver | Pull-out | V-n Diagram
      • Lecture-4 | V-n Diagram | Corner Speed | Maneuver Point | Revision | PYQs
    • Landing & Take-Off Performance
      • Lecture-1| Discussion | Lift Off Distance | Factors that influence Lift Off Distance | PYQs
      • Lecture-2 | Landing Distance | Derivation | Numerical | PYQs
      • Lecture-3 |Types of Wind: its effect on Range & Endurance ,Takeoff & Landing Distance | Horizontal & Vertical Load Factor |PYQs
      • Lecture-4 | Approach, Flare & Ground Roll Distance | Special Topics: Sideslip Angle & Angle of Attack | Numerical | PYQs
  • Aircraft Structures
    • Symmetrical & Unsymmetrical Bending
      • Lecture-1 | Centroid, MOI & POI and its Properties| Parallel Axis Theorem & Perpendicular Axis Theorem
      • Lecture-2| Moment of Inertia (MOI) | Product of Inertia (POI) | Numerical | Exercise Questions
      • Lecture-3| Thin Walled-Sections | Assumptions | MOI & POI | Numerical & Exercise Questions | PYQs
      • Lecture-4| Structural Idealization | Boom & Shear web | Its Properties | MOI & POI | Numerical | Exercise Questions
      • Lecture-5| Symmetric & Unsymmetrical Bending |Neutral Axis & Its Position | Sign Convention
      • Lecture-6| Unsymmetrical Bending Numerical | Exercise Questions | PYQs
      • Lecture-7 | Symmetrical Bending | Exercise Questions |Numerical | PYQs
    • Flexural Shear Flow & Shear Center
      • Lecture-1| Shear center & its Properties | Its Location for Open & Close Sections | Numerical | PYQs
      • Lecture-2| Open Cross-Section | Shear Flow Distribution | Shear Centre Calculation | Exercise Problems & Numerical |PYQs
      • Lecture-3| Idealized Sections| Shear Flow Distribution & Shear Centre in Boom Sections | Exercise Problems | PYQs
      • Lecture-4| Thin Cylinders | Hoop Stresses | Axial Stresses | Strains | Exercise Problems & Numerical | PYQs
    • Theory of Columns
      • Lecture-1| Buckling Load | End Conditions| Slenderness ratio | Buckling & Crushing
      • Lecture-2 | End Conditions or BCs |Safe Load FOS |Buckling Load & Buckling Stress | Exercise Questions | PYQs
      • Lecture-3| Exercise Problems | Numerical & PYQs
    • Deflection of Beams
      • Lecture-1| Types of Beam , Supports & BCs | Determinant & Indeterminant Structures | Degree of Indeterminacy | Numerical | PYQs
      • Lecture-2 |Double integration method | Principle of Superposition| Exercise Problems | PYQs
      • Lecture-3 |Energy Method | Castigliano's Theorems | Unit Load Method | Exercise Questions |PYQs
      • Lecture-4 | Deflection of Non-Prismatic Beams | Exercise Questions | Numerical | PYQs
    • Torsion of Shafts | Torsion of Thin walled Tubes
      • Lecture-1 | Torsion of Shafts | Torsional Rigidity | Max Shear Stress & its Plane| Twisting Angle
      • Lecture-2| Torsion of Shafts| Strength of Hollow & Solid Shafts| Torsional Stiffness| Numerical
      • Lecture-3| Torsion of Shafts| Series & parallel Shafts| Composite shafts| Strength & Stiffness Criteria of Shaft Design| Numeric
      • Lecture- 4| Torsion of Thin walled tubes | Open Sections | Torsional Constant| Exercise Problems| PYQs
      • Lecture-5| Close thin walled Sections & its Properties| Torsional Constant| Shear flow & Shear Stress| Breadt-Batho Formula| Num
      • Lecture-6| Multi-Cell Thin Sections| Twist per unit Length| Shear Flow & Shear stress Distribution |Exercise Problems | PYQs
      • Lecture-7| Torsion of Thin walled Close & Open Sections | REVISION | Numerical | Discussion | PYQs
    • Principal Stress & Principal Strain
      • Lecture-1| Concept of Principal Planes & Maximum Shear Planes | Principal stresses & Strains | Exercise Problems | PYQs
      • Lecture-2| Stresses on inclined plane | Orientation of Principal planes & Max shear stress plane | Numerical
      • Lecture-3| Exercise Questions | Numerical Mohr's Circle | PYQs
    • Theory of Failure
      • Lecture-1 | Classification of TOFs| Its Limitations based on Ductile & Brittle Materials | Numerical | PYQs
      • Lecture-2| Theory of Failures | Exercise Questions | Numerical | PYQs
    • Theory of Elasticity
  • Aircraft Propulsion
    • Previous Year Questions (PYQs)
      • Practice Set-I | Performance Parameters of Jet Engines
      • Aircraft Propulsion | PYQs
      • Axial Flow Compressors | PYQs
      • Axial Flow Turbines | PYQs
      • Centrifugal Compressors | PYQs
    • Gas Turbine Engines & Performance Parameters of Jet Engines
      • Lecture-1|Jet Propulsion & Turbomachines | SFEE & Its Application |Combustion Chamber ,Its Efficiency & Fuel to Air Ratio
      • Lecture-2 |Efficiencies | Thrust Power | Fuel Power | Turbojet Engines | Ramjet & Scramjet Engines
      • Lecture-3 |Numerical | Turbojet Engines | TSFC | Specific Thrust| Efficiencies | PYQs
      • Lecture-4 | Turbofan Engines | Fan/ Cold Thrust | Hot/Core Thrust | Efficiencies | Numerical | PYQs
    • Turbojet Engines
      • Lecture-5 | Gas Turbine Cycle | Brayton Cycle
      • Lecture-6 | Efficiency of jet engine components | Fuel to air ratio | After-Burner | Choked & Unchoked nozzle condition
      • Lecture-7 | Exercise Questions | Numerical | | Intake | Diffuser | Compressor | Combustor | Turbine | PYQs Solution
      • Lecture-8 | Exercise Questions | Ideal Engine Cycle| % Change in Exit Area, Thrust &TSFC due to After-Burner| Max mass Flow Rate
    • Ramjet Engines & Scramjet Engines
      • Lecture-9 | Ramjet Engines | Ideal Ramjet Engines| Thrust & Specific Thrust| TSFC| Propulsive Efficiency | Numerical | PYQs
    • Combustion Chemistry | Stoichiometric & Equivalence Ratio
      • Lecture-10 | Combustion Chemistry| Stoichiometric Ratio | Equivalence Ratio | Exercise Problems | Numerical
      • Lecture-11 | Exercise Question| Numerical| Stoichiometry & Equivalence Ratio| Moles of Air & Oxygen is required | PYQs
      • Lecture-12 | Combustion Chemistry | Pressure Loss Factor (PLF) | Cold Losses | Hot Losses
    • Fundamental of Turbomachines / Rotating Machines
      • Lecture-13| Fundamental of Rotating Machines | Principal | Energy Transfer & Energy Transformation
      • Lecture-14 |Euler's Energy Equation | Impulse Effect | Centrifugal Effect | Reaction Effect
    • Centrifugal Compressors
      • Lecture-15| Working Principal | Ideal Work | Slip Factor | Inlet & Exit Velocity Triangle
      • Lecture-16 | Actual Work | Inlet Velocity Triangle (with IGV & without IGV)| Numerical | Exercise Questions
      • Extra Lecture | Revision| Numerical | Exercise Question
      • Extra Lecture | Numerical | PYQs
      • Extra Lecture | PYQs | Review of Thermodynamics | Gas Dynamics
      • Lecture-17 | Exercise Questions | Numerical | Homework | PYQs
    • Axial Flow Compressors
      • Lecture-18| Euler's Equation for AFC| Stage and Overall pressure ratio| Number of stages | Numerical
      • Lecture-19 | Stage work | Degree of Reaction | Specific Stage work | Required stages| Stage efficiency | Overall efficiency
      • Lecture-20 | 50 % Reaction Stage | Low Reaction Stage | High Reaction Stage | Numerical | PYQs
      • Lecture-21 | Exercise Questions | Numerical | PYQs
      • Lecture-22 | AFC | Previous Year Questions (PYQs) | Solution
    • Axial Flow Turbines
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