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Linear Models
Study Course Description
Course Description Statuss:Approved
Course Description Version:5.00
Study Course Accepted:14.03.2024 11:46:46
| Study Course Information | |||||||||
| Course Code: | SL_112 | LQF level: | Level 7 | ||||||
| Credit Points: | 4.00 | ECTS: | 6.00 | ||||||
| Branch of Science: | Mathematics; Theory of Probability and Mathematical Statistics | Target Audience: | Life Science | ||||||
| Study Course Supervisor | |||||||||
| Course Supervisor: | Māris Munkevics | ||||||||
| 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) | 12 | Lecture Length (academic hours) | 2 | Total Contact Hours of Lectures | 24 | ||||
| Classes (count) | 12 | Class Length (academic hours) | 2 | Total Contact Hours of Classes | 24 | ||||
| Total Contact Hours | 48 | ||||||||
| Part-Time - Semester No.1 | |||||||||
| Lectures (count) | 12 | Lecture Length (academic hours) | 1 | Total Contact Hours of Lectures | 12 | ||||
| Classes (count) | 12 | Class Length (academic hours) | 2 | Total Contact Hours of Classes | 24 | ||||
| Total Contact Hours | 36 | ||||||||
| Study course description | |||||||||
| Preliminary Knowledge: | Calculus; Probability. | ||||||||
| Objective: | This course gives students the in-depth knowledge of the theory of linear models and provides training for applying the theory to solve practical problems. The software package R will be used for computation and independently prepared data analysis projects. | ||||||||
| Topic Layout (Full-Time) | |||||||||
| No. | Topic | Type of Implementation | Number | Venue | |||||
| 1 | Introduction to linear models. Examples: regression, ANOVA. Method of least squares for estimating the model parameters. | Lectures | 1.00 | auditorium | |||||
| 2 | Introduction to the software for estimating linear models. | Classes | 1.00 | computer room | |||||
| 3 | Maximum likelihood method for estimating the parameters, geometric interpretation. | Lectures | 1.00 | auditorium | |||||
| 4 | Interpreting model parameters. Interactions. | Classes | 1.00 | computer room | |||||
| 5 | Linear functions of parameters. T-test for testing hypothesis about parameters, confidence intervals. | Lectures | 1.00 | auditorium | |||||
| 6 | Example analysis (data with run-in period/ modelling a breakpoint). | Classes | 1.00 | computer room | |||||
| 7 | Gauss-Markov theorem, BLUE (best linear unbiased estimator). | Lectures | 1.00 | auditorium | |||||
| 8 | Example analysis. Research questions requiring a customised contrast/linear function of parameters. | Classes | 1.00 | computer room | |||||
| 9 | Prediction of a new observation, prediction interval. Coefficient of determination, R2. | Lectures | 1.00 | auditorium | |||||
| 10 | Estimating a growth curve with prediction intervals. Use of polynomials/splines to model non-linear relationship. | Classes | 1.00 | computer room | |||||
| 11 | F-test for comparing models. | Lectures | 1.00 | auditorium | |||||
| 12 | Comparing models. Different types of tests (type I/type III SS). | Classes | 1.00 | computer room | |||||
| 13 | Power of a F-test, geometric interpretation of F-test. | Lectures | 1.00 | auditorium | |||||
| 14 | Planning of a study. Sample size required to achieve the desired power. | Classes | 1.00 | computer room | |||||
| 15 | Overparameterised models, different parameterisations. | Lectures | 1.00 | auditorium | |||||
| 16 | Example analysis – interpretation of parameters, comparing estimates from differently parameterised models. | Classes | 1.00 | computer room | |||||
| 17 | Concepts of model building. Mallows Cp criterion, Akaike information criterion (AIC), Bayesian information criterion (BIC), stepwise regression. | Lectures | 1.00 | auditorium | |||||
| 18 | Model selection examples. Correct model might not always be the best choice, | Classes | 1.00 | computer room | |||||
| 19 | Model assumptions. Theoretical properties of residuals, leverage, standardized residuals. | Lectures | 1.00 | auditorium | |||||
| 20 | Analysis of a problematic dataset I. | Classes | 1.00 | computer room | |||||
| 21 | Model diagnostics, graphs for checking model assumptions. Transformations for treating non-normality and heteroscedasticity. Approximating non-linear relationship with splines or polynomials. | Lectures | 1.00 | auditorium | |||||
| 22 | Analysis of a problematic dataset II. | Classes | 1.00 | computer room | |||||
| 23 | Multiple testing I. Tukey HSD, tests and confidence intervals based on multivariate t-distribution. | Lectures | 1.00 | auditorium | |||||
| 24 | Multiple comparisons. | Classes | 1.00 | computer room | |||||
| Topic Layout (Part-Time) | |||||||||
| No. | Topic | Type of Implementation | Number | Venue | |||||
| 1 | Introduction to linear models. Examples: regression, ANOVA. Method of least squares for estimating the model parameters. | Lectures | 1.00 | auditorium | |||||
| 2 | Introduction to the software for estimating linear models. | Classes | 1.00 | computer room | |||||
| 3 | Maximum likelihood method for estimating the parameters, geometric interpretation. | Lectures | 1.00 | auditorium | |||||
| 4 | Interpreting model parameters. Interactions. | Classes | 1.00 | computer room | |||||
| 5 | Linear functions of parameters. T-test for testing hypothesis about parameters, confidence intervals. | Lectures | 1.00 | auditorium | |||||
| 6 | Example analysis (data with run-in period/ modelling a breakpoint). | Classes | 1.00 | computer room | |||||
| 7 | Gauss-Markov theorem, BLUE (best linear unbiased estimator). | Lectures | 1.00 | auditorium | |||||
| 8 | Example analysis. Research questions requiring a customised contrast/linear function of parameters. | Classes | 1.00 | computer room | |||||
| 9 | Prediction of a new observation, prediction interval. Coefficient of determination, R2. | Lectures | 1.00 | auditorium | |||||
| 10 | Estimating a growth curve with prediction intervals. Use of polynomials/splines to model non-linear relationship. | Classes | 1.00 | computer room | |||||
| 11 | F-test for comparing models. | Lectures | 1.00 | auditorium | |||||
| 12 | Comparing models. Different types of tests (type I/type III SS). | Classes | 1.00 | computer room | |||||
| 13 | Power of a F-test, geometric interpretation of F-test. | Lectures | 1.00 | auditorium | |||||
| 14 | Planning of a study. Sample size required to achieve the desired power. | Classes | 1.00 | computer room | |||||
| 15 | Overparameterised models, different parameterisations. | Lectures | 1.00 | auditorium | |||||
| 16 | Example analysis – interpretation of parameters, comparing estimates from differently parameterised models. | Classes | 1.00 | computer room | |||||
| 17 | Concepts of model building. Mallows Cp criterion, Akaike information criterion (AIC), Bayesian information criterion (BIC), stepwise regression. | Lectures | 1.00 | auditorium | |||||
| 18 | Model selection examples. Correct model might not always be the best choice, | Classes | 1.00 | computer room | |||||
| 19 | Model assumptions. Theoretical properties of residuals, leverage, standardized residuals. | Lectures | 1.00 | auditorium | |||||
| 20 | Analysis of a problematic dataset I. | Classes | 1.00 | computer room | |||||
| 21 | Model diagnostics, graphs for checking model assumptions. Transformations for treating non-normality and heteroscedasticity. Approximating non-linear relationship with splines or polynomials. | Lectures | 1.00 | auditorium | |||||
| 22 | Analysis of a problematic dataset II. | Classes | 1.00 | computer room | |||||
| 23 | Multiple testing I. Tukey HSD, tests and confidence intervals based on multivariate t-distribution. | Lectures | 1.00 | auditorium | |||||
| 24 | Multiple comparisons. | Classes | 1.00 | computer room | |||||
| Assessment | |||||||||
| Unaided Work: | • Individual work with the course material in preparation to 12 lectures and 12 shorts (1-3 question) Moodle tests after each lecture according to plan. • Independently prepare 2 data analysis projects. 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 data analysis projects – 30%. • 12 homeworks – 20%. • Final written exam – 50%. | ||||||||
| Final Examination (Full-Time): | Exam (Written) | ||||||||
| Final Examination (Part-Time): | Exam (Written) | ||||||||
| Learning Outcomes | |||||||||
| Knowledge: | • as a result of completion of a study course, the student is able to demonstrate an in-depth knowledge of the theory behind linear models; • explain the limitations and assumptions of the linear models; • discuss the different parameterisation options in linear models. | ||||||||
| Skills: | Is able to independently: • choose appropriate model for the data and check the model assumptions; • interpret and use (predictions; inference) the estimated model; • perform multiple comparisons and post-hoc tests. | ||||||||
| Competencies: | The students will be able to: • solve prediction problems using linear models’ methodology. • use linear models to answer complex what-if questions (Example: what would the average difference between male and female blood pressure be, if the proportion of overweight population would be the same for both genders?). • critically assess the linear models used in scientific publications and the validity of the conclusions made by authors. | ||||||||
| Bibliography | |||||||||
| No. | Reference | ||||||||
| Required Reading | |||||||||
| 1 | Faraway, J.J. Linear Models with R. Taylor & Francis group, 2014. | ||||||||
| 2 | Christensen, R. Plane answers to complex questions - the theory of linear models. Springer, 2011. | ||||||||
| Additional Reading | |||||||||
| 1 | Harville, D.A. Matrix Algebra From a Statistician's Perspective. Springer, 2008. | ||||||||
| 2 | Puntanen, S., Styan, G. and Isotalo, J. Matrix tricks for Linear Statistical Models. Springer, 2011. | ||||||||
