Machine Learning Theory

Spring 2026 (weeks 6 - 21). Lectures on Thursday 14:00-16:45 at the UvA, room SP C1.112.

Aim

Machine learning is one of the fastest growing areas of science, with far-reaching applications. In this course we focus on the fundamental ideas, theoretical frameworks, and rich array of mathematical tools and techniques that power machine learning. The course covers the core paradigms and results in machine learning theory with a mix of probability and statistics, combinatorics, information theory, optimization and game theory.

During the course you will learn to

Formalize learning problems in statistical and game-theoretic settings.
Examine the statistical complexity of learning problems using the core notions of complexity.
Analyze the statistical efficiency of learning algorithms.
Master the design of learning strategies using proper regularization.

This course strongly focuses on theory. (Good applied master level courses on machine learning are widely available, for example here, here and here). We will cover statistical learning theory including PAC learning, VC dimension, Rademacher complexity and Boosting, as well as online learning including prediction with expert advice, online convex optimisation, bandits and reinforcement learning.

MasterMath Website

This course is offered as part of the MasterMath program. To participate for credit, sign up here. We use the MasterMath ELO for submitting homework, and receiving grades.

We use the MasterMath ELO for announcements and as our student forum.

Prerequisites

The prerequisites are

Basic probability theory (in particular conditional probability, expectations, discrete and continuous distributions, Markov's and Hoeffding's inequalities)
Basic linear algebra (finite dimensional vector spaces, positive definite matrices, singular value decomposition)
Basic calculus (differentiation and minimisation of multivariate convex functions)

as covered e.g. in any bachelor mathematics program in the Netherlands, and as reviewed in the Appendix of the book [1]. The course does require general 'mathematical maturity', in particular the ability to combine insights from all three fields when proving theorems.

We offer weekly homework sets whose solution requires constructing proofs. This course will not include any programming or data.

Lecturers

Wouter M. Koolen (CWI, UT)
Tim van Erven (UvA)

The lectures will be held on location at the UvA, room SP C1.112.

The Thursday 3h slot will consist of 2h of lectures followed by a 1h TA session discussing the homework.

Grading

We provide weekly homework sets. Even sets are graded and must be handed in before the next lecture. Odd sets are for practice.

The grade will be composed as follows.

20%: even homework sets to be handed in biweekly.
40%: written mid-term exam.
40%: written final exam.

The average of midterm and final exam grades has to be at least 5.0 to pass the course.

There will be a retake possibility for either or both exams, which are 70% of the grade. The homework still counts as part of the grade after the retake.

It is allowed and strongly encouraged to solve and submit the homework in small teams. Exams are personal.

NB Collaboration on homework is only allowed within a team. In particular, solutions may

not be copied from the web, math exchange, stack overflow, ...
not be copied from other teams
not be from the instructors manual
not be generated by AI (chatGPT)

When using any source that is not on the official literature list, always cite the source.

Schedule

Wk	When	What	Lect.	TA
6	Thu 5 Feb	Introduction. Statistical learning. Halfspaces. PAC learnability for finite hyp. classes, realizable case. Chapters 1 and 2 in [1].	Tim	N/A
7	Thu 12 Feb	PAC learnability for finite hyp. classes, agnostic case. Uniform convergence. Chapters 3 and 4 in [1].	Tim	Roy
8	Thu 19 Feb	Infinite classes. VC Dimension part 1. Chapter 6.1-6.3 in [1].	Tim	Tygo
9	Thu 26 Feb	VC Dimension part 2. Fundamental theorem of PAC learning. Sauer's Lemma. Chapter 6 in [1].	Wouter	Roy
10	Thu 5 Mar	Proof of Fund.Th of PAC Learning. Rademacher Complexity part 1. Section 28.1 in [1].	Tim	Tygo
11	Thu 12 Mar	Nonuniform Learnability, SRM, Other notions of Learning. Sections 7.1 and 7.2 in [1] (note the errata about this chapter). Rademacher Complexity part 2. Chapter 26 in [1].	Tim	Roy
12	Thu 19 Mar	Generalisation of deep neural networks. Double descent. This material is not part of either exam.	Tim	Tygo
13	Thu 26 Mar	Midterm exam 14:00-17:00 on material covered in lectures 1-6.
14	Thu 2 Apr	Full Information Online Learning (Experts).	Tim	Roy
15	Thu 9 Apr	Bandits. UCB and EXP3.	Wouter	Roy
16	Thu 16 Apr	Online Convex Optimization.	Wouter	Tygo
17	Thu 23 Apr	Exp-concavity. Online Newton Step.	Wouter	Roy
18	Thu 30 Apr	Boosting. AdaBoost. Chapter 10 in [1].	Wouter	Tygo
19	Thu 7 May	Log-loss prediction. Normalised Maximum Likelihood. book chapter on ELO.	Wouter	Roy
20	Thu 14 May	Holiday (Ascension Day)
21	Thu 21 May	Part 2 special topic. This material is not part of either exam.	Wouter	Tygo
24	Thu 11 Jun	Final exam 14:00-17:00
27	Thu 2 Jul	Retake exam(s) 14:00-17:00

Course Material

The first half of the course will use the book

[1] Understanding Machine Learning: From Theory to Algorithms by Shai Shalev-Shwartz and Shai Ben-David. See here for errata.

The second half of the course will use slides posted above and on the ELO.

For going beyond the course

Consult these references to learn more

[2] Introduction to Online Convex Optimization by Elad Hazan.
[3] Regret Analysis of Stochastic and Nonstochastic Multi-armed Bandit Problems by Sébastien Bubeck and Nicolò Cesa-Bianchi.