Course detail
Statistics in Telecommunications
FEKT-GSTKAcad. year: 2019/2020
The proposed structure of the subject focuses on the use of selected mathematical techniques in modern communication signal processing and wireless communication theory. The goal is to present students with master's degree program Electronics and Communication Engineering specialized mathematical apparatus, which is essential to understanding the principles of modern wireless communications.
Language of instruction
English
Number of ECTS credits
4
Mode of study
Not applicable.
Guarantor
Department
Offered to foreign students
Of all faculties
Learning outcomes of the course unit
Students after completing the course should be able to solve problems associated with verification and testing assumptions and properties of the investigated phenomena and data files in the telecommunications field. The student is able to: (1) quantifying the probability of the event, (2) distinguishing between the random variables and describe their characteristics, (3) to test the hypothesis by parametric and non-parametric way, (4) describe the probability density by Gaussian mixture models, (5) estimating the shape of the spectrum and identify the spectral components, (6) identify and test the presence of a signal in noise.
Prerequisites
A student who register the course should be able to:
- To compose a simple program in Matlab
- Practicing a mathematical calculation procedures
- To compose a simple program in Matlab
- Practicing a mathematical calculation procedures
Co-requisites
Not applicable.
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations. Techning methods include lectures, computer laboratories.
Assesment methods and criteria linked to learning outcomes
Requirements for completion of a course are specified by a regulation issued by the lecturer responsible for the course and updated for every. Test written during semester (30 points), final oral+ writting test exam (70 points).
Course curriculum
Lectures:
1. Calculations on the discrete and the continuous distribution of random variables. Simulation in Matlab.
2. The simulation of the distribution of the data set and its estimation in Matlab.
3. Calculation of confidence intervals, the derivation of system reliability.
4. Testing the significance of the estimates, the parametric and the nonparametric approach.
5. Examples of Gaussian mixed models.
6. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
7. Spectrum estimation techniques (parametric and nonparametric methods).
8. Gaussian mixed models.
9. Random processes.
10. Spectrum estimation techniques (parametric and nonparametric methods).
11. Detection of hidden signals in noises. ROC curve.
12. Applications - time-frequency analysis.
13. 10. Orthogonal transformation, Karhunen-Loev transformation, PCA.
Computer exercises:
1. Calculations on the discrete and the continuous distribution of random variables. Simulation in Matlab.
2. The simulation of the distribution of the data set and its estimation in Matlab.
3. Calculation of confidence intervals, the derivation of system reliability.
4. Testing the significance of the estimates, the parametric and the nonparametric approach.
5. Examples of Gaussian mixed models.
6. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
7. Application of estimation methods on simulated signal spectrum.
1. Calculations on the discrete and the continuous distribution of random variables. Simulation in Matlab.
2. The simulation of the distribution of the data set and its estimation in Matlab.
3. Calculation of confidence intervals, the derivation of system reliability.
4. Testing the significance of the estimates, the parametric and the nonparametric approach.
5. Examples of Gaussian mixed models.
6. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
7. Spectrum estimation techniques (parametric and nonparametric methods).
8. Gaussian mixed models.
9. Random processes.
10. Spectrum estimation techniques (parametric and nonparametric methods).
11. Detection of hidden signals in noises. ROC curve.
12. Applications - time-frequency analysis.
13. 10. Orthogonal transformation, Karhunen-Loev transformation, PCA.
Computer exercises:
1. Calculations on the discrete and the continuous distribution of random variables. Simulation in Matlab.
2. The simulation of the distribution of the data set and its estimation in Matlab.
3. Calculation of confidence intervals, the derivation of system reliability.
4. Testing the significance of the estimates, the parametric and the nonparametric approach.
5. Examples of Gaussian mixed models.
6. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
7. Application of estimation methods on simulated signal spectrum.
Work placements
Not applicable.
Aims
The proposed structure of the subject focuses on the use of selected mathematical techniques in modern communication signal processing and wireless communication theory. The goal is to present students with master's degree program Electronics and Communication Engineering specialized mathematical apparatus, which is essential to understanding the principles of modern wireless communications.
Specification of controlled education, way of implementation and compensation for absences
Evaluation of activities is specified by a regulation, which is issued by the lecturer responsible for the course annually.
Recommended optional programme components
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
KOBAYASHI, H. et al. Probability, random processes, and statistical analysis, Cambridge University Press, 2012. (EN)
Recommended reading
GOPI, E.S. Algorithm Collections for Digital Signal Processing Applications Using Matlab, Springer, 2007. (EN)
KAY, S. Intuitive Probability and Random Processing using MATLAB, Springer 2005. (EN)
KAY, S. Intuitive Probability and Random Processing using MATLAB, Springer 2005. (EN)
Classification of course in study plans
Type of course unit
Lecture
26 hod., optionally
Teacher / Lecturer
Syllabus
1. Introduction to the subject, probability theory, dependent and independent experiments, conditional probability.
2. Distribution of one-dimensional discrete random variables and its characteristics.
3. Distribution of one-dimensional continuouse random variables and its characteristics.
4. Multinomial random variables.
5. The central limit theorem and the law of large numbers.
6. Introduction to the theory of statistics, point and interval estimation, confidence intervals.
7. Hypothesis testing, the parametric and the nonparametric approach.
8. Gaussian mixed models.
9. Random processes.
10. Orthogonal transformation, Karhunen-Loev transformation, PCA.
11. Spectrum estimation techniques (parametric and nonparametric methods).
12. Detection of hidden signals in noises. ROC curve.
13. Applications - time-frequency analysis.
2. Distribution of one-dimensional discrete random variables and its characteristics.
3. Distribution of one-dimensional continuouse random variables and its characteristics.
4. Multinomial random variables.
5. The central limit theorem and the law of large numbers.
6. Introduction to the theory of statistics, point and interval estimation, confidence intervals.
7. Hypothesis testing, the parametric and the nonparametric approach.
8. Gaussian mixed models.
9. Random processes.
10. Orthogonal transformation, Karhunen-Loev transformation, PCA.
11. Spectrum estimation techniques (parametric and nonparametric methods).
12. Detection of hidden signals in noises. ROC curve.
13. Applications - time-frequency analysis.
Exercise in computer lab
13 hod., compulsory
Teacher / Lecturer
Syllabus
1. Calculations on the discrete and the continuous distribution of random variables. Simulation in Matlab. The simulation of the distribution of the data set and its estimation in Matlab.
2. Calculation of confidence intervals, the derivation of system reliability. Testing the significance of the estimates, the parametric and the nonparametric approach.
3. Examples of Gaussian mixed models.
4. Examples of orthogonal transformation.
5. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
6. Application of estimation methods on simulated signal spectrum.
2. Calculation of confidence intervals, the derivation of system reliability. Testing the significance of the estimates, the parametric and the nonparametric approach.
3. Examples of Gaussian mixed models.
4. Examples of orthogonal transformation.
5. Calculation and testing for the presence of signal in the channel, goodness of fit tests.
6. Application of estimation methods on simulated signal spectrum.