FU:TFNSP0003 Mathematic. Methods in Physics - Course Information
TFNSP0003 Mathematical Methods in Physics
Institute of physics in Opavawinter 2020
- Extent and Intensity
- 3/2/0. 7 credit(s). Type of Completion: zk (examination).
- Teacher(s)
- RNDr. Filip Blaschke, Ph.D. (lecturer)
RNDr. Martin Blaschke, Ph.D. (seminar tutor) - Guaranteed by
- RNDr. Filip Blaschke, Ph.D.
Institute of physics in Opava - Timetable
- Thu 13:55–16:20 425
- Timetable of Seminar Groups:
- Prerequisites (in Czech)
- (FAKULTA(FU) && TYP_STUDIA(N))
- Course Enrolment Limitations
- The course is also offered to the students of the fields other than those the course is directly associated with.
- fields of study / plans the course is directly associated with
- Particle physics (programme FU, TFYZNM)
- Computer physics (programme FU, TFYZNM)
- Relativistic astrophysics (programme FU, TFYZNM)
- Course objectives
- The goal of this course is to introduce students to the most important mathematical tools used in physics. These fall into three broad categories: i) Complex analysis, ii) discrete calculus and iii) Ordinary differential equations. The emphasis is placed on practical calculations while rigorous presentation ala definition-theorem-proof is deemphasized.
- Learning outcomes
- By completing the course the student should be capable of:
- basic orientation in complex analysis;
- solve proper real integrals as contour integrals in the complex plane;
- find exact solutions to discrete and recurrent equations;
- find exact solutions to differential equations;
- find approximations to solutions of differential equations via perturbation and asymptotic methods;
- find approximations to energy levels and asymptotic behavior of the wave functions for a general one-dimensional Schroedinger equation. - Syllabus
- The main topics are:
• Introduction to discrete calculus. The primitive function theorem, inverse operator to indefinite summation. Discrete product and its inverse operator. Finding solutions to simple recurrence equations.
• Binomial numbers and related identities. Integral representation. Stirling numbers and other special sequences.
• Introduction to complex analysis. Analytic function, Riemann-Cauchy conditions. Cauchy's theorem.
• Classification of singularities in the complex plane. Laurent series and Residue theorem.
• Computation of proper integrals via techniques of complex analysis.
• Solving general linear differential equations. Classification of singular points. Taylor series. Airy equation.
• Frobenius series as a solution to the differential equation in its regular-singular point. Modified Bessel equation.
• Introduction to asymptotic methods. Definition of the asymptotic relation. Method of dominant balance.
• Perturbation series and its convergence. Divergent series. Pade series.
• WKB method. An approximate solution to inhomogeneous differential equations.
• Sturm-Liouville problem. Asymptotic solution of the Schroedinger equation with a single turning point. Global approximation.
• WKB approximation of the Schroedinger equation with two turning points and semiclassical quantization condition.
• Exact solution to selected Schroedinger equations.
- The main topics are:
- Literature
- recommended literature
- Bender, I. C. M., Orszag, S. A. Advanced Mathematical Methods for Scientists and Engineers, Springer, 1999
- GRAHAM, R., KNUTH, D., PATASHNIK, O. Concrete Mathematics. Addison-Wesley, New York, 1992. info
- REKTORYS, K. a spol. Přehled užité matematiky 2. Praha : Prometheus, 2000. ISBN 80-7196-181-7. info
- Teaching methods
- Live lectures in front of the blackboard or presentation in front of a projector. Showcasing of approximative solutions in Mathematica software.
- Assessment methods
- The written examination followed by a discussion with the teacher.
- Language of instruction
- Czech
- Enrolment Statistics (winter 2020, recent)
- Permalink: https://is.slu.cz/course/fu/winter2020/TFNSP0003