FU:TFADPV003 Numerical methods in physics - Course Information
TFADPV003 Numerical methods in physics
Institute of physics in Opavawinter 2020
- Extent and Intensity
- 0/0/0. Type of Completion: dzk.
- Guaranteed by
- doc. RNDr. Jan Schee, Ph.D.
- Prerequisites
- Good knowledge of basic chapters of numerical methods in physics is expected:
- Solution of systems of linear equations (LU-decomposition, tridiagonal systems),
- Polynomial interpolation and extrapolation,
- Orthogonal polynomials,
- Numerical integration using Gaussian quadratures,
- Numerical solution of transcendental equations (Brent's method),
- Search for minima of 1D and 2D functions,
- Solution of ordinary differential equations - Runge-Kutha scheme,
- Random number generators. - Course Enrolment Limitations
- The course is only offered to the students of the study fields the course is directly associated with.
- fields of study / plans the course is directly associated with
- Theoretical physics and Astrophysics (programme FU, TFAD) (2)
- Course objectives
- The aim of the course is to develop knowledge of basic chapters of numerical methods in physics (see Prerequisites of the course) and to gain knowledge of more advanced chapters of numerical methods in physics at the highest level reflecting the current state of research.
- Learning outcomes
- It depends on the individual study plan of the student.
- Syllabus
- Particular advanced chapters of numerical methods in physics and their content are selected for the content of the course within the individual study plan so that they are directly related to the topic of the dissertation and at the same time suitably complement parts of other compulsory optional courses of the student's individual study plan.
The chapters could be, for example:
- Interpolation using a cubic spline,
- Ordinary differential equations (Rung-Kuth scheme with adaptive step, Richardson extrapolation, Bulirsh-Stroyer method, methods based on predictor-corrector),
- Problems with boundary conditions (shooting method, relaxation methods),
- Integral equations (Fredholm's equation of the second kind, Volterra's equation),
- Integro-differential equations (radiant transfer equations),
- Partial differential equations (classification, FTCS, Leapfrog, Lax-Wendroff, SOR),
- Monte-Carlo methods of integration, simulation,
- Numerical solution of Regge-Wheeler equation with boundary conditions and determination of stationary modes.
- Particular advanced chapters of numerical methods in physics and their content are selected for the content of the course within the individual study plan so that they are directly related to the topic of the dissertation and at the same time suitably complement parts of other compulsory optional courses of the student's individual study plan.
The chapters could be, for example:
- Literature
- Press W.H., Teukolsky S.A., Vetterling W.T., Flannery B. P., Numerical Recipes: The Art of Scientific Computing, Cambridge University Press (2007)
- Hoffman J.D. and Frankel S., Numerical Methods for Engineers and Scientists, CRC Press, Taylor & Francis Group (2001)
- Hutchinson I. H., A Student‘s Guide to Numerical Methods, Cambridge University Press (2015)
- Giordano N.J. and Nakanishi H., Computational Physics, Pearson (2005)
- Teaching methods
- self-study, discussions
- Assessment methods
- exam
- Language of instruction
- Czech
- Further comments (probably available only in Czech)
- The course can also be completed outside the examination period.
- Teacher's information
- Enrolment Statistics (winter 2020, recent)
- Permalink: https://is.slu.cz/course/fu/winter2020/TFADPV003