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Probability
Study Course Description
Course Description Statuss:Approved
Course Description Version:5.00
Study Course Accepted:07.09.2023 09:07:25
| Study Course Information | |||||||||
| Course Code: | SL_104 | LQF level: | Level 7 | ||||||
| Credit Points: | 2.00 | ECTS: | 3.00 | ||||||
| Branch of Science: | Mathematics; Theory of Probability and Mathematical Statistics | Target Audience: | Life Science | ||||||
| Study Course Supervisor | |||||||||
| Course Supervisor: | Eva Petrošina | ||||||||
| Study Course Implementer | |||||||||
| Structural Unit: | Statistics Unit | ||||||||
| The Head of Structural Unit: | |||||||||
| Contacts: | 14 Baložu street, Riga, statistika rsu[pnkts]lv, +371 67060897 | ||||||||
| Study Course Planning | |||||||||
| Full-Time - Semester No.1 | |||||||||
| Lectures (count) | 8 | Lecture Length (academic hours) | 2 | Total Contact Hours of Lectures | 16 | ||||
| Classes (count) | 4 | Class Length (academic hours) | 2 | Total Contact Hours of Classes | 8 | ||||
| Total Contact Hours | 24 | ||||||||
| Part-Time - Semester No.1 | |||||||||
| Lectures (count) | 8 | Lecture Length (academic hours) | 1 | Total Contact Hours of Lectures | 8 | ||||
| Classes (count) | 4 | Class Length (academic hours) | 2 | Total Contact Hours of Classes | 8 | ||||
| Total Contact Hours | 16 | ||||||||
| Study course description | |||||||||
| Preliminary Knowledge: | Knowledge in calculus. | ||||||||
| Objective: | This course introduces students to probability and random variables and introduces probability with applications in order to get knowledge on fundamental probability concepts. | ||||||||
| Topic Layout (Full-Time) | |||||||||
| No. | Topic | Type of Implementation | Number | Venue | |||||
| 1 | Combinatorial Analysis (the basic principle of counting; permutations; combinations; multinomial coefficients). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 2 | Axioms of Probability (sample spaces and events; axioms of probability; sample spaces having equally likely outcomes). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 3 | Conditional Probability and Independence (conditional probabilities; Bayes' formula; independent events). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 4 | Random Variables (discrete RVs; expectation; variance; Bernoulli and binomial RVs; the Poisson RV; sums of RVs; cumulative distribution function). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 5 | Continuous Random Variables (expectation and variance again; uniform RV; normal RV; exponential RV; functions of RV). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 6 | Jointly Distributed Random Variables (joint distribution functions; independent RVs; sums of independent RVs; conditional distributions (discrete and continuous cases); order statistics; joint distribution of functions of RVs). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 7 | Expectation (expectation of sums of RVs; moments of event counting functions; covariance, correlation, and variance of sums; conditional expectation; prediction; moment generating functions). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 8 | Limit Theorems (Chebyshev's inequality; weak law of large numbers; central limit theorem; strong law of large numbers). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| Topic Layout (Part-Time) | |||||||||
| No. | Topic | Type of Implementation | Number | Venue | |||||
| 1 | Combinatorial Analysis (the basic principle of counting; permutations; combinations; multinomial coefficients). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 2 | Axioms of Probability (sample spaces and events; axioms of probability; sample spaces having equally likely outcomes). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 3 | Conditional Probability and Independence (conditional probabilities; Bayes' formula; independent events). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 4 | Random Variables (discrete RVs; expectation; variance; Bernoulli and binomial RVs; the Poisson RV; sums of RVs; cumulative distribution function). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 5 | Continuous Random Variables (expectation and variance again; uniform RV; normal RV; exponential RV; functions of RV). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 6 | Jointly Distributed Random Variables (joint distribution functions; independent RVs; sums of independent RVs; conditional distributions (discrete and continuous cases); order statistics; joint distribution of functions of RVs). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 7 | Expectation (expectation of sums of RVs; moments of event counting functions; covariance, correlation, and variance of sums; conditional expectation; prediction; moment generating functions). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| 8 | Limit Theorems (Chebyshev's inequality; weak law of large numbers; central limit theorem; strong law of large numbers). | Lectures | 1.00 | computer room | |||||
| Classes | 0.50 | computer room | |||||||
| Assessment | |||||||||
| Unaided Work: | 1) Literature studies on each of 8 topics of each lecture. 2) 2 homeworks on the following topics: • Combinatorial Analysis, Axioms of Probability and Conditional Probability and Independence. • Random Variables, Continuous Random Variables and Jointly Distributed Random Variables, Expectation and Limit Theorems. In order to evaluate the quality of the study course as a whole, the student must fill out the study course evaluation questionnaire on the Student Portal. | ||||||||
| Assessment Criteria: | Assessment on the 10-point scale according to the RSU Educational Order: • 2 homeworks, each one counting 30% of the final grade; • written exam 40%. | ||||||||
| Final Examination (Full-Time): | Exam (Written) | ||||||||
| Final Examination (Part-Time): | Exam (Written) | ||||||||
| Learning Outcomes | |||||||||
| Knowledge: | The student will: 1) independently define event, outcome, trial, simple event, sample space and calculate the probability that an event will occur; 2) demonstrate deeper knowledge in fundamental probability concepts, including random variable, probability of an event, additive rules and conditional probability, Bayes’ theorem; 3) recognize, distinguish and use the basic statistical concepts and measures; 4) recognize and comprehend several well-known distributions. | ||||||||
| Skills: | The student will have skills to: 1) derive probability distributions of functions of random variables; 2) derive expressions for measures such as the mean and variance of common probability distributions using calculus and algebra; 3) calculate probabilities for joint distributions including marginal and conditional probabilities; 4) develop the concept of the central limit theorem. | ||||||||
| Competencies: | The student will be competent to: 1) to evaluate and solve problems independently; 2) prove some basic theorems of probability theory; 3) choose appropriately and apply the central limit theorem to sampling distributions. | ||||||||
| Bibliography | |||||||||
| No. | Reference | ||||||||
| Required Reading | |||||||||
| 1 | Ross, S. M. A First Course in Probability. 9th edition, Pearson, 2014. | ||||||||
| Additional Reading | |||||||||
| 1 | Morin, D. Probability. CreateSpace, 2016. | ||||||||
| 2 | Dekking, F. M., Meester, L. E., Lopuhaä, H. P. and Kraaikamp, C. A. Modern Introduction to Probability and Statistics: Understanding Why and How. Springer, 2007. | ||||||||
