Course details

Numerical Methods and Probability

INM Acad. year 2017/2018 Winter semester 5 credits

Current academic year

Numerical mathematics: Metric spaces, Banach theorem. Solution of nonlinear equations. Approximations of functions, interpolation, least squares method, splines. Numerical derivative and integral. Solution of ordinary differential equations, one-step and multi-step methods. Probability: Random event and operations with events, definition of probability, independent events, total probability. Random variable, characteristics of a random variable. Probability distributions used, law of large numbers, limit theorems. Rudiments of statistical thinking.

Guarantor

Language of instruction

Czech

Completion

Credit+Examination (written)

Time span

  • 26 hrs lectures
  • 13 hrs exercises
  • 13 hrs pc labs

Assessment points

  • 70 pts final exam (35 pts written part, 35 pts test part)
  • 30 pts mid-term test (15 pts written part, 15 pts test part)

Department

Lecturer

Instructor

Subject specific learning outcomes and competences

Students apply the gained knowledge in technical subjects when solving projects and writing the BSc Thesis. Numerical methods represent the fundamental element of investigation and practice in the present state of research.

Learning objectives

In the first part the student will be acquainted with some numerical methods (approximation of functions, solution of nonlinear equations, approximate determination of a derivative and an integral, solution of differential equations) which are suitable for modelling various problems of practice. The other part of the subject yields fundamental knowledge from the probability theory (random event, probability, characteristics of random variables, probability distributions) which is necessary for simulation of random processes.

Prerequisite knowledge and skills

Secondary school mathematics and some topics from Discrete Mathematics and Mathematical Analysis courses.

Study literature

  • Fajmon, B., Hlavičková, I., Novák, M., Vítovec, J.: Numerická matematika a pravděpodobnost (Informační technologie), VUT v Brně, 2014
  • Hlavičková, I., Hliněná, D.: Matematika 3. Sbírka úloh z pravděpodobnosti. VUT v Brně, 2015
  • Hlavičková, I., Novák, M.: Matematika 3 (zkrácená celoobrazovková verze učebního textu). VUT v Brně , 2014
  • Novák, M.: Matematika 3 (komentovaná zkoušková zadání pro kombinovanou formu studia). VUT v Brně, 2014
  • Novák, M.: Mathematics 3 (Numerical methods: Exercise Book), 2014

Fundamental literature

  • Ralston, A.: Základy numerické matematiky. Praha, Academia, 1978.
  • Horová, I.: Numerické metody. Skriptum PřF MU Brno, 1999.
  • Maroš, B., Marošová, M.: Základy numerické matematiky. Skriptum FSI VUT Brno, 1997.
  • Loftus, J., Loftus, E.: Essence of Statistics. Second Edition, Alfred A. Knopf, New York 1988.
  • Taha, H.A.: Operations Research. An Introduction. Fourth Edition, Macmillan Publishing Company, New York 1989.
  • Montgomery, D.C., Runger, G.C.: Applied Statistics and Probability for Engineers. Third Edition. John Wiley & Sons, Inc., New York 2003.

Syllabus of lectures

  1. Introduction to numerical methods.
  2. Numerical solution of linear systems.
  3. Numerical solution of non-linear equations and systems.
  4. Approximation, interpolation.
  5. Numercial integration and differentiation.
  6. ODE's: Introduction, numerical solution of first-order initial value problems.
  7. Introduction to statistics, vizualization of statistical data.
  8. Introduction to probability theory, probability models, conditional and complete probability.
  9. Discrete and continuous random variables.
  10. Selected discrete distributions of probability.
  11. Selected continuous distributions of probability.
  12. Statistical testing.
  13. Reserve, revision, consultations.

Syllabus of numerical exercises

  1. Classical and geometric probabilities.
  2. Discrete and continuous random variables.
  3. Expected value and dispersion.
  4. Binomial distribution.
  5. Poisson and exponential distributions.
  6. Uniform and normal distributions, z-test.
  7. Mean value test, power.

Syllabus of computer exercises

  1. Nonlinear equation: Bisection method, regula falsi, iteration, Newton method.
  2. System of nonlinear equtations, interpolation.
  3. Splines, least squares method.
  4. Numerical differentiation and integration.
  5. Ordinary differential equations, analytical solution.
  6. Ordinary differential equations, analytical solution.

Progress assessment

To pass written tests with at least 10 points.

Controlled instruction

Ten written tests.

Course inclusion in study plans

  • Programme IT-BC-3, field BIT, 2nd year of study, Compulsory
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