ME 681: Mathematics for Engineers
Instructor: Anurag Gupta (ag@)
Teaching assistants: Animesh Pandey, Manish Singh, Tushar Joshi, Romil
Schedule: TF 2-3:30 pm, L10
Grading policy: HW (20%), MT (30%), Final (50%)
Primary text:
Linear Algebra
[1] Linear algebra and its applications, 4th Edition, G. Strang. [You can easily get a copy of this book, available in Indian edition, either from one of the bookstores in the shopping centre or from one of the online bookstores.]
ODE
[1] An Introduction to Ordinary Differential Equations, by E. A. Coddington
Additional texts:
Linear Algebra
[2] Lectures on linear algebra, I. M. Gelfand (available as a cheap dover edition)
[3] Finite-dimensional vector spaces, P. Halmos (available in Indian edition)
Course notes:
Lecture 1: Linear equations; Gauss elimination; LU decomposition (Ch. 1 of [1])
Lecture 2: Gauss-Jordon method for finding inverse; Vector spaces (Ch.1 and Ch. 2 of [1]; see also Ch. I of [2])
Assignment 1 (due on 17/1/17) Solution
Lecture 3: Basis and coordinates; Subspace; Coordinate transformation; inner produce space (Ch. 2 of [1]; see also Ch. I of [2])
Assignment 2 (due on 24/1/17) Solution
Lecture 4: Linear transformations (Ch. 2 of [1]; see also Ch. II of [2]
Lecture 5: Eigenvalues and eigenvectors; characteristic polynomial
Lecture 6: Complex inner product spaces; adjoint; self-adjoint transformations
Assignment 3 (due on 31/1/17) Solution
Lecture 7: Unitary transformation; commutative linear transformations; Diagonalization; Decomposition into positive definite and unitary transformations
Lecture 8: Linear transformations on Real Euclidean spaces; Symmetric transformations; orthogonal transformations and their canonical form
Assignment 4 (due on 07/2/17) Solution
Lecture 9: General solution to Ax=b; column space, null space, echelon form
Lecture 10: Column space, null space, row space, and left null space
Assignment 5 (due on 17/2/17) Solution
Lecture 11: Projections and least square method
Lecture 12: Gram-Schmidt process; QR factorization
Assignment 6 (due on 21/2/17) Solution
Lecture 13: Eigenvalue problem; applications to differential equations and difference equations
Lecture 14: Jordan canonical form of an arbitrary matrix; application to linear ODEs
Assignment 7 (due on 07/3/17) Solution
Lecture 15: Vector and tensor calculus; fields; differentiability of a scalar field; gradient; directional derivative
Lecture 16: Gradient of vector and tensor fields; divergence; curl; Laplacian
Assignment 8 (due on 21/3/17) Solution
Lecture 17: Integral theorems; localization theorem; divergence theorem; Stokes theorem; transport theorem
Lecture 18: Introduction to ODEs; linear first order ODEs; linear ODEs with constant coefficients
Assignment 9 (due on 04/4/17) Solution
Lecture 19: linear ODEs with constant coefficients; second order homogeneous and inhomogeneous equation
Lecture 20: n-th order linear order with constant coefficients
Assignment 10 (due on 18/4/17) Solution
Lecture 21: Linear ODEs with variable coefficients
Lecture 22: Linear ODEs with regular singular points
Lecture 23: Bessel Equations