Short Course Description
Differential and Integral Equations
Lecturer: Boris Melamed (Malomed)
Credits: 3
Instruction language: Englsih
Remark: if the semester is not long enough, some advanced items may be dropped
A full videorecord of the course taught in Hebrew is available at:
http://video.tau.ac.il/index.php?option=com_videos&Itemid=53&lang=en
Then select Faculty/Department: No. 0510
Then select course No. 5001
Partial differential equations (PDEs): general introduction (it includes the derivation of the "master equation", namely, a generalized multidimensional sine-Gordon equation, from which a majority of classical PDEs, both linear and nonlinear ones, can be obtained as particular and limit cases). Classification of classical linear second-order PDEs: elliptic, hyperbolic, and parabolic equations; transformation of generic equations, belonging to this class, into canonical forms. A brief introduction to more sophisticated PDEs (Klein-Gordon, Helmholtz, Schroedinger, sine-Gordon, and Burgers equations). The initial-value (Cauchy) problem, and boundary-value problems (of the Dirichlet, Neumann, and mixed types). Stability of solutions and well-posedness of the PDEs. The solution of the Cauchy problem for the one-dimensional (1D) D'Alembert equation (traveling waves). Solutions of Cauchy problem for the 1D diffusion equation in finite regions (with boundary conditions) in the form of Fourier series. The Green's function and
solution of the Cauchy problem for the 1D diffusion equation in the infinite domain. The Green's function for two- and three-dimensional (2D and 3D) Poisson equations, and an elementary introduction to the theory of renormalization for singular solutions (using the 2D Poisson equation as an example). Distributions (the Dirac's delta-function and related functions). Quasi-linear PDEs of the first order and the method of characteristics; the problem of caustics. The Burgers equation, shock waves, and the Rankine-Hugoniot relation, as the regularization of singular solutions of the quasi-linear equations. Introduction to nonlinear PDEs: the Korteweg - de Vries equation, nonlinear Schroedinger equation, and elementary soliton solutions. Hyperbolic systems of first-order linear PDEs; the spectrum and characteristics. Integral equations: classification; Fredholm equations, separable kernels, and an
explicit solution of homogeneous Fredholm equations with degenerate kernels. Hermitian kernels with real spectra of eigenvalues and the orthogonality of the respective eigenfunctions. The Hilbert-Schmidt method for solutions of inhomogeneous integral equations with the Hermitian kernel. The Neumann's series (iterative approximations for inhomogeneous integral equations).
Textbooks:
Garabedian P.R., Partial Differential Equations, Chelsea, 1964.
Hildebrand F.B., Advanced Calculus for Applications, 2nd ed., Prentice Hall, 1976.
Hildebrand F.B., Methods of Applied Math, 2nd ed., Prentice Hall, 1965.
Stephenson G., Partial Differential Equations for Scientists and Engineers,
Imperial College Press, 3rd ed., 1985.
Advanced reading: Witham G. B., Linear and Nonlinear Waves, John Wiley & Sons, Inc., 1999.
Preliminary requirements: introductory courses on ordinary and partial differential equations.
Full syllabus is to be published