II SEM
Galois Theory-AM201
Paper - I
Course Outcomes
1.Explain the fundamental concepts of advanced algebra and their role in modern mathematics and applied contexts
2.Demonstrate accurate and efficient use of advanced algebraic techniques
3.Demonstrate capacity for mathematical reasoning through analyzing, proving and explaining concepts from advanced algebra
4.Apply problem-solving using advanced algebraic techniques applied to diverse situations in physics, engineering and other mathematical sciemces
Unit-I
Algebraic extensions of fields: Irreducible polynomials and Eisenstein criterion.
Adjunction of roots.
Algebraic extensions.
Algebraically closed fields.
Unit-II
Splitting fields.
Normal extensions.
Multiple roots.
Finite fields.
Separable extensions.
Unit-III
Galois theory: Automorphism groups and fixed fields.
Fundamental theorem of Galois theory.
Fundamental theorem of Algebra.
Unit-IV
Applications of Galois theory to classical problems.
Roots of unity and cyclotomic polynomials.
Cyclic extensions.
Polynomials solvable by radicals.
Ruler and Compass constructions.
Text Book:
Basic Abstract Algebra by S.K. Jain, P.B. Bhattacharya, S.R. Nagpaul.
References:
[1] Topics in Algebra by I.N. Herstein.
[2] Elements of Modern Algebra by Gibert& Gilbert.
[3] Abstract Algebra by Jeffrey Bergen.
[4] Basic Abstract Algebra by Robert B Ash.
Lebesgue Measure & Integration-AM202
Paper-II
Course Outcomes
1.Define concepts within measurement theory
2.Formulate and prove theorems in measurement theory
3.Define basic concepts within Banach and operator theory
4.Use above-mentioned theory within applications
Unit-I
Algebra of sets-Borelsets.
Outermeasure.
Measurable sets and Lebesgue measure.
Anon-measurable set.
Measurable functions.
Littlewood three principles.
Unit-II
The Riemannintegral.
TheLebesgue integral of a bounded function over a set of finitemeasure.
The integral of a non-negative function.
The general Lebesgue integral.
Unit-III
Convergence in measure.
Differentiation of a monotone functions.
Functions of bounded variation.
Unit-IV
Differentiation of an integral-Absolutecontinuity.
TheLp-spaces.
The Minkowski and Holder's inequalities.
Convergence and completeness.
TextBook:
Real Analysis (3rd Edition)(Chapters3,4,5)byH.L.RoydenPearsonEducation(LowPriceEdition).
References:
[1] LebesguemeasureandIntegration byG.deBarra.
[2] Measure andIntegral byRichardL.Wheeden,AnotoniZygmund.
Complex Analysis-AM203
Paper-III
Course Outcomes
1.Define a function of complex variable and carry out basic mathematical operations with complex numbers.
2.Know the condition(s) for a complex variable function to be analytic and/or harmonic
3.State and prove the Cauchy Riemann Equation and use it to show that a function is analytic
4.Define singularities of a function, know the different types of singularities, and be able to determine the points of singularities of a function
Unit-I
Regions in the Complex Plane.
Functions of a Complex Variable-Mappings-Mappings by the Exponential Function.
Limits-Limits Involving thePoint at In nity.
Continuity-Derivatives-Cauchy{RiemannEquations -Su cientConditionsforDi erentiability.
Analytic Functions.
Harmonic Functions.
Uniquely Determined Analytic Functions.
Reection Principle.
The Exponential Function.
The Logarithmic Function -Some Identities Involving Logarithms.
ComplexExponents-Trigonometric Functions-Hyperbolic Functions.
Unit-II
Derivatives of Functions w(t) -De niteIntegrals of Functions w(t).
Contours-Contour Integrals-Some Examples -Examples with BranchCuts Upper Bounds for Moduli of Contour Integrals{Antiderivatives.
Cauchy{GoursatTheorem-Simply Connected Domains-Multiply Connected Domains-Cauchy Integral Formula- An Extension of the Cauchy Integral Formula.
Liouville'sTheorem.
The Fundamental Theorem of Algebra-Maximum Modulus Principle.
Unit-III
Convergence of Sequences.
Convergence of Series.
Taylor Series-Laurent Series.
Absolute and Uniform Convergence of Power Series.
Continuity of Sums of Power Series.
Integration and Di erentiation of Power Series.
Uniqueness of Series Representations.
Isolated Singular Points.
Residues-Cauchy's ResidueThe-orem -Residue at In nity.
TheThreeTypes of Isolated Singular Points-Residues at Poles-Examples-
Zeros of Analytic Functions-Zeros and Poles.
Behavior of Functions Near Isolated Singular Points.
Unit-IV
Evaluation of Improper Integrals.
Improper Integrals from Fourier Analysis.
Jordan'sLemma-Indented Paths
De niteIntegrals nvolving Sines and Cosines.
Argument Principle.
Rouche's Theorem.
Linear Transformations-TheTransformation w = 1=z - Mappingsby1=z .
Linear Fractional Transformations.
AnImplicit Form-Mappings of the Upper Half Plane.
TextBook:
Complex Variableswithapplications byJamesWardBrown,RuelVChurchill.
References:
[1] ComplexAnalysisbyDennisG.Zill.
[2] ComplexVariablesbyStevanG.Krantz.
[3] ComplexVariableswithApplicationsbyS.Ponnusamy,HerbSilverman.
[4] ComplexAnalysisbyJosephBak,DonaldJ.Newman.
Fluid Mechanics-AM204
Paper - IV
Course Outcomes
1.State the Newton’s law of Viscosity and Explain the mechanics of fluids at rest and in motion by observing the fluid phenomena.
2.Compute Force of Buoyancy on a partially or fully submerged body and Analyze the stability of a floating body.
3.Derive Euler’s Equation of Motion and Deduce Bernoulli’s Equation.
4.Examine energy losses in pipe transitions and sketch energy gradient lines
Unit-I
General Orthogonal Curvilinear Coordinates.
Definition Kinematics of fluids in motion.
Real fluids and ideal fluids.
velocity of a fluid at a point.
Lagrangian and Eulerian methods.
stream lines, path lines and streak lines.
steady and unsteady flows.
The velocity potential.
the vorticity vector.
Local and particle rates of change.
Acceleration of fluid.
The Equation of Continuity (Vector and Cartesian form).
conditions at a rigid boundary.
Unit-II
Equations of Motion of Fluid.
Euler’s equations of motion (Vector and Cartesian form).
Lagrange’s equations of Motion.
Equation in one dimensional flow problems.
Bernoulli’s Theorem.
Kelvins circulation theorem.
Motion in two dimension.
velocity potential.
Stream function.
physical meaning of stream function.
Unit-III
Some Two Dimensional Flows.
The complex potential.
Irrotational motion.
Stream function.
Source, Sinks and Doublets and their Images.
General theory of Irrotational.
Milne Thomson Circle Theorem.
Applications of circle theorem.
The Magnus effect.
The Therorem of Blasius.
Unit-IV
Irrotational Motion in Two Dimensions.
Two - dimensional Irrotational motion produced by motion of circular cylinder.
two coaxial cylinders.
Equations of motion of a circular cylinder.
Ellliptic coordinate.
Motion of an Elliptic cylinder.
Text Books: [1] Textbook of Fluid Dynamics by FRANK CHORLTON, CBS - Publishers, New Delhi,India. [2] A Treatise on Hydro - Mechanics (Part - II) by W.H.BESANT and A.S.RAMSEY, CBS - Publishers, New Delhi, India
References: [1] Fluid Dynamics by M.D.RAISINGHANIA S.Chand & Company, New Delhi. [2] Introduction to Fluid Mechanics by Edward J. Shanghnessy [3] Flow Visualization by Merzkirch. 19 DEPARTMENT OF MATHEMATICS OSMANIA UNIVERSITY M.Sc. Applied Mathematics AM/M 205 Semester - II Paper - V: Theory of Ordinary Differential Equations
Theory of Ordinary Differential Equations-AM205
Paper-V
Course Outcomes
1.Analyze real world scenarios to recognize when ordinary differential equations (ODEs) or systems of ODEs are appropriate, formulate problems about the scenarios, creatively model these scenarios (using technology, if appropriate) in order to solve the problems using multiple approaches, judge if the results are reasonable, and then interpret and clearly communicate the results.
2.Recognize ODEs and system of ODEs concepts that are encountered in the real world.
3.Work with ODEs and systems of ODEs in various situations and use correct mathematical terminology, notation, and symbolic processes in order to engage in work, study, and conversation on topics involving ODEs and systems of ODEs with colleagues in the field of mathematics, science or engineering
4.Understand and be able to communicate the underlying mathematics involved to help another person gain insight into the situation.
Unit-I (Linear differential equations of higher order)
Introduction-Higher order equations.
A Modelling problem, Linear Independence.
Equations with constant coe cients
Equations with variable coe cients.
Wronskian.
Variation of parameters.
Some Standard methods.
Unit-II (Existence and uniqueness of solutions)
Introduction-Preliminaries.
Successive approximations,Pi-card's theorem.
Continuation and dependence on intial conditions.
Existence of solutions in the large.
Existence and uniqueness of solutions of systems.
Fixed point method.
Unit-III (Analysis and methods ofnon-linear differential equations)
Introduction-Existence theorem.
Extremal solutions-Upper and Lower solutions.
Monotone iterative method.
method of quasi linearization.
Bihari'sinequality,Application of Bihari's inequality.
Unit-IV (Oscillation theory for linearDifferential Equation of Second order)
The adjoint equation-Self adjoin.
linear di erential equation of second order.
Abel'sformula.
The number of zeros in a niteinterval.
The sturm separation theorem.
The strum comparison theorem.
The sturm picone theorem.
Bocher Osgood theorem.
A special pair of solution-Oscillation on half axis.
TextBook:
[2] TextbookofOrdinaryDi erentialEquation, ByS.G.Deo,V.LakshmiKantham,V.Raghavendra,
TataMc.GrawHillPub.CompanyLtd.
References:
[1] TextBookofOrdinaryDi erentialEquations byEarlACoddington.
[2] Di erentialEquations byEdward,Penny,Calvis.
[3] Di erentialEquation byHarryHochstardt.