|
#1
24th December 2020, 08:24 AM
| |||
| |||
 Sathyabama Institute of Science and Technology B.E. - Electronics and Communication Engineering Part Time SMTA1401 Engineering Mathematics - IV Syllabus SATHYABAMA INSTITUTE OF SCIENCE AND TECHNOLOGY SCHOOL OF BUILDING AND ENVIRONMENT SMTA1401 ENGINEERING MATHEMATICS - IV (COMMON TO ALL BRANCHES EXCEPT BIO GROUPS, CSE AND IT) L T P Credits Total Marks 3 * 0 3 100 UNIT 1 FOURIER SERIES 9 Hrs. Fourier series – Euler’s formula – Dirichlet’s conditions – Fourier series for a periodic function – Parseval’s identity (without proof) – Half range cosine series and sine series – simple problems – Harmonic Analysis. UNIT 2 APPLICATIONS OF PARTIAL DIFFERENTIAL EQUATION 9 Hrs. One dimensional wave equation – Transverse vibrating of finite elastic string with fixed ends – Boundary and initial value problems – One dimensional heat equation – Steady state problems with zero boundary conditions – Two dimensional heat equation – Steady state heat flow in two dimensions- Laplace equation in Cartesian form( No derivations required). UNIT 3 NUMERICAL METHODS FOR SOLVING EQUATIONS 9 Hrs. Solution of algebraic equation and transcendental equation: Regula Falsi Method, Newton Raphson Method (including solving algebraic equations in two variables f(x,y)=0 and g(x,y)=0) – Solution of simultaneous linear algebraic equations: Gauss Elimination Method, Gauss Jacobi & Gauss Seidel Method. UNIT 4 INTERPOLATION, NUMERICAL DIFFERENTATION &INTEGRATION 9 Hrs. Interpolation: Newton forward and backward interpolation formula, Lagrange’s formula for unequal intervals – Numerical differentiation: Newton’s forward and backward differences to compute first and second derivatives – Numerical integration: Trapezoidal rule, Simpson’s 1/3rd rule and Simpson’s 3/8th rule. UNIT 5 NUMERICAL SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS AND PARTIAL DIFFERENTIAL EQUATIONS 9 Hrs. Ordinary differential equations: Taylor series method, Runge Kutta method for fourth order – Partial differential equations – Finite differences – Laplace equation and its solutions by Liebmann’s process – Solution of Poisson equation – Solutions of parabolic equations by Bender Schmidt Method – Solution of hyperbolic equations. Max. 45 Hrs. COURSE OUTCOMES On completion of the course, student will be able to CO1 - List the formulae in Fourier series, algebraic and transcendental equations. Recall the condition for convergence of simultaneous linear algebraic equations. CO2 - Understand various numerical methods for Interpolation, differentiation and integration. CO3 - Apply the concepts of ordinary and partial differential equations by choosing the most suitable numerical method. CO4 - Categorize and implement the numerical solutions of algebraic, transcendental, simultaneous linear equations. CO5 - Appraise the solution of one dimensional wave, one dimensional heat and two dimensional heat equations. CO6 - Develop Fourier series for different types of functions. Evaluate solution for Interpolation, numerical differentiation and integration. TEXT / REFERENCE BOOKS 1. Kreyszig E., "Advanced Engineering Mathematics", (8th Edition), John Wiley and Sons (Asia)Pte Ltd., Singapore, 2001. 2. Grewal B.S., "Higher Engineering Mathematics", 41th Edition, Khanna Publications, Delhi,2011. 3. Kandasamy P., Thilagavathy K. & Gunavathy K.,"Engineering Mathematics", (4th Revised Edition), S.Chand & Co., New Delhi, 2001. 4. Veerarajan,T., "Engineering Mathematics", Tata Mcgraw Hill Publishing Co., New Delhi, 2005. 5. Steven C. Chapra, Raymond P. Canale, "Numerical Methods for Engineers", Tata McGraw Hill Publishing Co., New Delhi, 2003. 6. Kandasamy P., Thilagavathy K., Gunavathy K., "Applied Numerical Methods", S.Chand & Co., New Delhi, 2003. END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks: 100 Exam Duration: 3 Hrs. PART A: 10 Questions of 2 marks each – No choice 20 Marks PART B: 2 Questions from each unit of internal choice; each carrying 16 marks 80 Marks   |
 |
| |
