(AE)
Engineering Mathematics
Linear
Algebra:
Matrix algebra, systems of
linear equations, eigen values and eigen vectors.
Calculus:
Functions of single
variable, limit, continuity and differentiability, mean value theorems,
evaluation of definite and
improper integrals, partial derivatives, total derivative, maxima
and minima, gradient,
divergence and curl, vector identities, directional derivatives, line,
surface and volume
integrals. Theorems of Stokes, Gauss and Green.
Differential
Calculus:
First order linear and
nonlinear equations, higher order linear ODEs with constant
coefficients, Cauchy and
Euler equations, initial and boundary value problems, Laplace
transforms. Partial
differential equations and separation of variables methods.
Numerical
methods:
Numerical solution of
linear and nonlinear algebraic equations, integration by
trapezoidal and Simpson
rule, single and multi-step methods for differential equations.
Flight Mechanics
Atmosphere:
Properties, standard
atmosphere. Classification of aircraft. Airplane (fixed wing aircraft)
configuration and various
parts.
Airplane
performance:
Pressure altitude;
equivalent, calibrated, indicated air speeds; Primary flight
instruments: Altimeter,
ASI, VSI, Turn-bank indicator. Drag polar; take off and landing;
steady climb &
descent,-absolute and service ceiling; cruise, cruise climb, endurance or
loiter; load factor,
turning flight, V-n diagram; Winds: head, tail & cross winds.
Static
stability:
Angle of attack, sideslip;
roll, pitch & yaw controls; longitudinal stick fixed & free stability,
horizontal tail position
and size; directional stability, vertical tail position and size;
dihedral stability. Wing
dihedral, sweep & position; hinge moments, stick forces.
Dynamic
stability:
Euler angles; Equations of
motion; aerodynamic forces and moments, stability & control
derivatives; decoupling of
longitudinal and lat-directional dynamics; longitudinal modes;
lateral-directional modes.
Space Dynamics
Central force motion,
determination of trajectory and orbital period in simple cases. Orbit
transfer, in-plane and
out-of-plane. Elements of rocket motor performance.
Aerodynamics
Basic
Fluid Mechanics:
Incompressible
irrotational flow, Helmholtz and Kelvin theorem, singularities and
superposition, viscous
flows, boundary layer on a flat plate.
Airfoils
and wings:
Classification of
airfoils, aerodynamic characteristics, high lift devices, Kutta Joukowski
theorem; lift generation;
thin airfoil theory; wing theory; induced drag; qualitative
treatment of low aspect
ratio wings.
Viscous
Flows:
Flow separation,
introduction to turbulence, transition, structure of a turbulent boundary
layer.
Compressible
Flows:
Dynamics and
Thermodynamics of I-D flow, isentropic flow, normal shock, oblique
shock, Prandtl-Meyer flow,
flow in nozzles and diffusers, inviscid flow in a c-d nozzle,
flow in diffusers.
subsonic and supersonic airfoils, compressibility effects on lift and
drag, critical and drag
divergence Mach number, wave drag.
Wind
Tunnel Testing:
Measurement and
visualisation techniques.
Structures
Stress
and Strain:
Equations of equilibrium,
constitutive law, strain-displacement relationship, compatibility
equations, plane stress
and strain, Airy's stress function.
Flight Vehicle
Structures:
Characteristics of
aircraft structures and materials, torsion, bending and flexural shear.
Flexural shear flow in
thin-walled sections. Buckling. Failure theories. Loads on aircraft.
Structural
Dynamics:
Free and forced vibration
of discrete systems. Damping and resonance. Dynamics of
continuous systems.
Propulsion
Thermodynamics of Aircraft
Gas Turbine engines, thrust and thrust augmentation.
Turbomachinery:
Axial compressors and
turbines, centrifugal pumps and compressors.
Aerothermodynamics
of non rotating propulsion components:
Intakes, combustor and
nozzle. Thermodynamics of ramjets and scramjets. Elements of
rocket propulsion.
Source: gate.iitd.ac.in
Edited by: http://ipuedu.blogspot.com
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