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Explanatory Notes
Instructions
Web page:
https://math.fel.cvut.cz/en/people/heliskat/01pst.html
Anotation:
The students will be introduced to the theory of probability and mathematical statistics, namely to the basic computing methods and their applications in practice. The course covers the basic parts of probability and mathematical statistics. The first part is focused on classical probability, including conditional probability. The next part deals with the theory of random variables and their distributions, examples of the most important types of discrete and continuous distributions, numerical characteristics of random variables, their independence, sums and transformations. Probabilistic knowledge is then used in the description of statistical methods for estimating distribution parameters and testing hypotheses.
Study targets:
The students will be introduced to the theory of probability and mathematical statistics, namely to the basic computing methods and their applications in practice.
Content:
The course covers the basic parts of probability and mathematical statistics. The first part is focused on classical probability, including conditional probability. The next part deals with the theory of random variables and their distributions, examples of the most important types of discrete and continuous distributions, numerical characteristics of random variables, their independence, sums and transformations. Probabilistic knowledge is then used in the description of statistical methods for estimating distribution parameters and testing hypotheses.
Course outlines:
1. | | Random events, probability, probability space. |
2. | | Conditional probability, Bayes' theorem, independent events. |
3. | | Random variable - definition, distribution function, probability function, density. |
4. | | Characteristics of random variables - expected value, variance and other moments. |
5. | | Discrete random variable - examples and usage. |
6. | | Continuous random variable - examples and usage. |
7. | | Independence of random variables, covariance, correlation. |
8. | | Transformation of random variables, sum of independent random variables (convolution). |
9. | | Random vector, covariance and correlation. |
10. | | Central limit theorem. |
11. | | Random sampling and basic statistics. |
12. | | Point estimates, maximum likelihood method and method of moments. |
13. | | Confidence intervals. |
14. | | Hypotheses testing. |
Exercises outline:
1. | | Combinatorics, random events, probability, probability space. |
2. | | Conditional probability, Bayes' theorem, independent events. |
3. | | Random variable - construction and usage of distribution function, probability function and density. |
4. | | Characteristics of random variables - expected value, variance. |
5. | | Discrete random variable - examples and usage. |
6. | | Continuous random variable - examples and usage. |
7. | | Independence of random variables, covariance, correlation. |
8. | | Transformation of random variables, sum of independent random variables (convolution). |
9. | | Random vector, joint and marginal distribution. |
10. | | Central limit theorem. |
11. | | Random sampling and basic statistics, point estimates, maximum likelihood method and method of moments. |
12. | | Confidence intervals. |
13. | | Hypotheses testing. |
14. | | Reserve. |
Literature:
[1] | | Papoulis, A.: Probability and Statistics, Prentice-Hall, 1990. |
[2] | | Stewart W.J.: Probability, Markov Chains, Queues, and Simulation: The Mathematical Basis of Performance Modeling. Princeton University Press 2009. |
Requirements:
Calculation of basic derivatives and integrals. Basics of combinatorics.
Keywords:
Probability, statistics.
Subject is included into these academic programs:
Page updated 7.12.2024 12:51:24, semester: Z,L/2024-5, Z/2025-6, Send comments about the content to the Administrators of the Academic Programs |
Proposal and Realization: I. Halaška (K336), J. Novák (K336) |