Corspedia | Mathematical Optimization for Engineers

Overview

Today, for almost every product on the market and almost every service offered, some form of optimization has played a role in their design.

However, optimization is not a button-press technology. To apply it successfully, one needs expertise in formulating the problem, selecting and tuning the solution algorithm and finally, checking the results. We have designed this course to make you such an expert.

This course is useful to students of all engineering fields. The mathematical and computational concepts that you will learn here have application in machine learning, operations research, signal and image processing, control, robotics and design to name a few.

We will start with the standard unconstrained problems, linear problems and general nonlinear constrained problems. We will then move to more specialized topics including mixed-integer problems; global optimization for non-convex problems; optimal control problems; machine learning for optimization and optimization under uncertainty. Students will learn to implement and solve optimization problems in Python through the practical exercises.

Syllabus

Week 1: Introduction and math review

Mathematical definitions of objective function, degrees of freedom, constraints and optimal solution with real-world examples
Review of some mathematical basics needed to take us through the course

Week 2: Unconstrained optimization

Basics of iterative descent: step direction and step length
Common algorithms like steepest descent, Newton’s method and its variants and trust-region methods.

Week 3: Linear optimization

KKT conditions of optimality for constrained problems
Simplex method
Interior point methods

Week 4: Nonlinear optimization

Penalty, log-barrier and SQP methods

Mixed-integer optimization

Branch and bound method for mixed-integer linear problems

Week 5: Global optimization

Branch and bound method for nonlinear non-convex problems
Constructing relaxations
Different formulations and their numerical performance
Stochastic methods, genetic algorithm and derivative free methods

Week 6: Dynamic optimization

Full discretization, single-shooting and multi-shooting methods
Nonlinear model predictive control

Week 7: Machine learning for optimization

Mechanistic, data-driven and hybrid modelling
Basics of training machine learning models
Optimization with machine learning embedded

Week 8: Optimization under uncertainty

Parametric optimization
Two stage stochastic problems
Robust optimization via semi-infinite problems

Taught by

Univ.-Prof. Alexander Mitsos, Johannes M. M. Faust and Ashutosh Manchanda

Mathematical Optimization for Engineers

بواسطة: edX

Overview

Syllabus

Taught by

Mathematical Optimization for Engineers

بواسطة: edX