The course will be concentrated mostly on theoretical aspects of first-order methods in optimization, e.g. gradient descent, accelerated gradient descent, mirror descent, AdaGrad. These methods are at their renaissance motivated by current big data world, which leads to large-scale problems with no need of very precise solution. One of the main assumptions in the course will be convexity of the objective function and some background from convex analysis will be given. Another cornerstone is randomness of different nature. One case is when the randomness is present in the problem itself, e.g. in stochastic optimization, for which stochastic gradient descent is usually applied. The second case is when the randomness is added to a deterministic problem by introducing randomization. In this case one can also apply stochastic gradient descent, as well as more sophisticated random coordinate descent or stochastic variance reduction methods. Non-convex optimization will also be discussed as many of the optimization problems in machine learning are non-convex.
Prerequisites: Multivariate calculus, Linear algebra, Basic probability
Preliminary program- Motivating examples from Machine Learning: regression, classification, neural networks.
- Oracle model, complexity, complexity of global optimization. Classes of optimization problems.
- Background from optimization theory: optimality conditions, Lagrange duality, Karush-Kuhn-Tucker conditions, Legendre-Fenchel conjugate duality.
- Non-smooth convex optimization: lower complexity bound, (composite) mirror descent, switching mirror descent.
- Smooth convex optimization: lower complexity bounds, mirror descent, accelerated gradient method, smoothing technique.
- Projection-Free Convex Optimization: Frank-Wolfe method.
- Mirror-prox method for variational inequalities.
- Stochastic convex optimization: lower bounds, stochastic mirror descent, stochastic accelerated gradient method.
- Adaptive methods in optimization: line search, AdaGrad, Adam.
- Optimization in optimal transport: Optimal transport distances and barycenters, primal-dual accelerated gradient methods.
Literature:
- A. Ben-Tal, A. Nemirovski
Lectures on Modern Convex Optimization
- G. Lan
Lectures on Optimization Methods for Machine Learning
- Yu. Nesterov
Introductory Lectures on Convex Optimization. A Basic Course
Springer-Verlag US, 2004 - Yu. Nesterov
Lectures on convex optimization
Springer, 2018 - John C. Duchi
Introductory Lectures on Stochastic Optimization,
2016