Statistical Learning Theory, Spring Semester 2017
Instructor
Prof. Dr. J.M. BuhmannAssistants
Luca CorinziaViktor Wegmayr
General Information
The ETHZ Course Catalogue information can be found here.
The course covers advanced methods of statistical learning. The fundamentals of Machine Learning as presented in the course "Introduction to Machine Learning" are expanded and, in particular, the following topics are discussed:
- Statistical Learning Theory: How can we measure the quality of a classifier? Can we give any guarantees for the prediction error?
- Variational Methods and Optimization: We consider
optimization approaches for problems where the optimizer is a
probability distribution. Concepts we will discuss in this context
include:
- Maximum Entropy
- Information Bottleneck
- Deterministic Annealing
- Clustering: The problem of sorting data into groups without using training samples. This requires a definition of ``similarity'' between data points and adequate optimization procedures;
- Model Selection: We have already discussed how to fit a model to a data set in ML I, which usually involved adjusting model parameters for a given type of model. Model selection refers to the question of how complex the chosen model should be. As we already know, simple and complex models both have advantages and drawbacks alike;
- Reinforcement Learning: The problem of learning through interaction with an environment which changes. To achieve optimal behavior, we have to base decisions not only on the current state of the environment, but also on how we expect it to develop in the future;:
Time and Place
| Type | Time | Place | |
|---|---|---|---|
| Lectures | Mon 14-16 | ML | H 44 |
| Exercises | Mon 16-18 | ML | H 44 |
Student Forum
Link to Forum Please feel free to use it for any questions, comments to the TA's, for sharing ideas and discussing assignments, projects and anything related to SLT with other students.Material
| Date | Lecture/Tutorial Slides | Exercise Series, Hometasks | Reading for Tutorial class | |
|---|---|---|---|---|
| Feb 20 | Lecture [pdf] Motivation [pdf] | Exercise [pdf] Solution [pdf] | LLE | |
| Feb 27 | Lecture [pdf] | Exercise [pdf] Solution [pdf] | MaxEntropy inference | |
| Mar 6 | Exercise [pdf] Solution [pdf] | 4.5 MCMC | ||
| Mar 13 | Lecture [pdf] Tutorial Notes [pdf] | Exercise [pdf] Solution [pdf] | Kmeans with complexity cost | |
| Mar 20 | Exercise [pdf] Solution [pdf] | Probabilistic PCA Mixture models and EM, Bishops | ||
| Mar 27 | Lecture [pdf] Tutorial Notes [pdf] | Exercise [pdf] Solution [pdf] SolutionBis [pdf] | PDC IBM | |
| Apr 3 | Lecture [pdf] | Exercise [pdf] Solution [pdf] | CSE | |
| Apr 10 | Lecture [pdf] |
Exercise [pdf] Solution [pdf] SolutionBis [pdf] | Ncut Pairwise-data clustering with DA | |
| May 8 | Lecture [pdf] | BIC | ||
| May 15 | Lecture [pdf] | Exercise [pdf] Solution [pdf] | DAEM ASC for GMM Hamming distance problem | |
| May 29 | Lecture [pdf] | Information content of sort-algorithm EM for linear regression |
Exam 2016
Projects
Projects are small coding exercises that concern the implementation of an algorithm taught in the lecture/exercise class. The final grade for the lecture is max(exam, 0.7 exam + 0.3 project).Students who wish to get the advantage of the project bonus need to submit reports about their coding excercises. There will be eight coding ecercises, and each report will be graded either as good, normal or not accepted/not submitted.
With no submitted/accepted reports, the project grade is 4.0. Each normal report increases the project grade by 0.25, while a good report increases it by 0.5. This means eight normal reports result in a project grade of 6.0 and good reports help you to compensate for not submitted/accepted reports. The maximum project grade is 6.0.
Note that even if you are not interested in doing the projects, the written exam might include problems addressed in the coding exercises.
Project repository Here you can find the coding exercise grades. Grades [pdf]
Reading
- Prelimiary course script (ver. 04 Aug 2015) (draft TeX by Sergio Solorzano). This script has not been fully checked and thus comes without any guarantees, however, is good for getting oriented in the material.
- Duda, Hart, Stork: Pattern Classification, Wiley Interscience, 2000.
- Hastie, Tibshirani, Friedman: The Elements of Statistical Learning, Springer, 2001.
- L. Devroye, L. Gyorfi, and G. Lugosi: A probabilistic theory of pattern recognition. Springer, New York, 1996
Web Acknowledgements
The web-page code is based (with modifications) on the one of the course on Machine Learning (Fall Semester 2013; Prof. A. Krause).