CSIR-UGC NET for Junior
Research Fellowship and Lecturer-ship
SYLLABUS FOR MATHEMATICAL SCIENCES
PAPER I (PART B) AND PAPER II
UNIT – 1
Analysis: Elementary set theory, finite,
countable and uncountable sets, Real number system as a complete ordered field,
Archimedean property, supremum, infimum. Sequences and series, convergence,
limsup, liminf. Bolzano Weierstrass theorem, Heine Borel theorem. Continuity,
uniform continuity, differentiability, mean value theorem. Sequences and series
of functions, uniform convergence. Riemann sums and Riemann integral, Improper
Integrals. Monotonic functions, types of discontinuity, functions of bounded
variation, Lebesgue measure, Lebesgue integral. Functions of several variables,
directional derivative, partial derivative, derivative as a linear
transformation. Metric spaces, compactness, connectedness. Normed Linear
Spaces. Spaces of Continuous functions as examples.
Linear Algebra: Vector spaces, subspaces,
linear dependence, basis, dimension, algebra of linear transformations. Algebra
of matrices, rank and determinant of matrices, linear equations.
Eigenvalues and eigenvectors, Cayley-Hamilton
theorem. Matrix representation of linear transformations. Change of basis,
canonical forms, diagonal forms, triangular forms, Jordan forms.
Inner product spaces, orthonormal basis. Quadratic
forms, reduction and classification of quadratic forms.
UNIT – 2
Complex Analysis: Algebra of complex
numbers, the complex plane, polynomials, Power series, transcendental functions
such as exponential, trigonometric and hyperbolic functions. Analytic
functions, Cauchy-Riemann equations. Contour integral, Cauchy’s theorem,
Cauchy’s integral formula, Liouville’s theorem, Maximum modulus principle,
Schwarz lemma, Open mapping theorem. Taylor series, Laurent series, calculus of
residues. Conformal mappings, Mobius transformations.
Algebra: Permutations, combinations,
pigeon-hole principle, inclusion-exclusion principle, derangements. Fundamental
theorem of arithmetic, divisibility in Z, congruences, Chinese Remainder
Theorem, Euler’s Ø- function, primitive roots. Groups, subgroups, normal
subgroups, quotient groups, homomorphisms, cyclic groups, permutation groups,
Cayley’s theorem, class equations, Sylow theorems. Rings, ideals, prime and
maximal ideals, quotient rings, unique factorization domain, principal ideal
domain, Euclidean domain.
Polynomial rings and irreducibility criteria. Fields,
finite fields, field extensions.
UNIT – 3
Ordinary Differential Equations
(ODEs):
Existence and Uniqueness of solutions of initial
value problems for first order ordinary differential equations, singular solutions
of first order ODEs, system of first order ODEs. General theory of homogenous
and non-homogeneous linear ODEs, variation of parameters, Sturm-Liouville
boundary value problem, Green’s function.
Partial Differential Equations
(PDEs):
Lagrange and Charpit methods for solving first order
PDEs, Cauchy problem for first order PDEs. Classification of second order PDEs,
General solution of higher order PDEs with constant coefficients, Method of
separation of variables for Laplace, Heat and Wave equations.
Numerical Analysis :
Numerical solutions of algebraic equations, Method of
iteration and Newton-Raphson method, Rate of convergence, Solution of systems
of linear algebraic equations using Gauss elimination and Gauss-Seidel methods,
Finite differences, Lagrange, Hermite and spline interpolation, Numerical
differentiation and integration, Numerical solutions of ODEs using Picard,
Euler, modified Euler and Runge-Kutta methods.
Variation of a functional, Euler-Lagrange equation,
Necessary and sufficient conditions for extrema. Variational methods for
boundary value problems in ordinary and partial differential equations.
Linear Integral Equations:
Linear integral equation of the first and second kind
of Fredholm and Volterra type, Solutions with separable kernels. Characteristic
numbers and eigenfunctions, resolvent kernel.
Classical Mechanics:
Generalized coordinates, Lagrange’s equations,
Hamilton’s canonical equations, Hamilton’s principle and principle of least
action, Two-dimensional motion of rigid bodies, Euler’s dynamical equations for
the motion of a rigid body about an axis, theory of small oscillations.
UNIT – 4
Descriptive statistics,
exploratory data analysis.
Sample space, discrete probability, independent events,
Bayes theorem. Random variables and distribution functions (univariate and
multivariate); expectation and moments. Independent random variables, marginal
and conditional distributions. Characteristic functions. Probability
inequalities (Tchebyshef, Markov, Jensen). Modes of convergence, weak and
strong laws of large numbers, Central Limit theorems (i.i.d. case). Markov
chains with finite and countable state space, classification of states,
limiting behaviour of n-step transition probabilities, stationary distribution.
Standard discrete and continuous univariate distributions. Sampling
distributions. Standard errors and asymptotic distributions, distribution of
order statistics and range. Methods of estimation. Properties of estimators.
Confidence intervals. Tests of hypotheses: most powerful and uniformly most
powerful tests, Likelihood ratio tests. Analysis of discrete data and
chi-square test of goodness of fit. Large sample tests. Simple nonparametric
tests for one and two sample problems, rank correlation and test for
independence. Elementary Bayesian inference. Gauss-Markov models, estimability
of parameters, Best linear unbiased estimators, tests for linear hypotheses and
confidence intervals. Analysis of variance and covariance. Fixed, random and mixed
effects models. Simple and multiple linear regression. Elementary regression
diagnostics. Logistic regression. Multivariate normal distribution, Wishart
distribution and their properties. Distribution of quadratic forms. Inference
for parameters, partial and multiple correlation coefficients and related
tests. Data reduction techniques: Principle component analysis, Discriminant
analysis, Cluster analysis, Canonical correlation. Simple random sampling,
stratified sampling and systematic sampling. Probability proportional to size
sampling. Ratio and regression methods. Completely randomized, randomized
blocks and Latin-square designs. Connected, complete and orthogonal block
designs, BIBD. 2K factorial experiments:
confounding and construction. Series and parallel systems, hazard function and
failure rates, censoring and life testing. Linear programming problem. Simplex
methods, duality. Elementary queuing and inventory models. Steady-state
solutions of Markovian queuing models: M/M/1, M/M/1 with limited waiting space,
M/M/C, M/M/C with limited waiting space, M/G/1.