Matrix Computations and Convex Optimization
2020/2021
Prerequisite/Recommended prerequisite for participation in the module
The module builds on knowledge from Linear Algebra/CalculusContent, progress and pedagogy of the module
Engineering systems and design problems can often be compactly described analyzed and manipulated using matrices and vectors. Moreover, tractable solutions to design problems can be obtained by casting the design problems as optimization problems. For the class of linear and quadratic problems, the solutions can be obtained by solving systems of equations. In computer programs, this is achieved via matrix factorizations. For the larger class of convex problems, no closed-form solution may exist and numerical methods must be applied. This course aims at teaching numerically robust methods for solving systems of equations and, more generally, convex optimization problems, including also standard constrained problems.
Learning objectives
Knowledge
- Knowledge about convex functions and sets, norms, special matrices
- Understand how to classify and solve systems of equations and convex optimization problems
- Understand numerical aspects of solving systems of equations and convex optimization problems
- Knowledge about Lagrange multipliers
- Understand matrix factorizations and their properties
Skills
- Identify optimization problems and cast them into standard form
- Identify types of extreme (minima, maxima, local, global, etc.)
- Apply eigenvalue and singular value decomposition to relevant matrix problems
- Have understanding of state space descriptions of systems of linear differential equations
- Apply numerically robust methods to solve systems of equations
- Apply and implement the following numerical optimization methods to unconstrained optimization problems: Steepest Descent, Newton's method, Gauss-Newton method
- Apply and interpret least-squares in solving over-determined systems of equations
- Apply the Lagrange multiplier method to constrained convex optimization problems
Competences
- Apply linear algebra theory to analyze engineering systems in their field
- State and analyze engineering design problems in their field as systems of equations or standard optimization problems
- Select the appropriate matrix factorization or numerical optimization method to solve engineering design problems in their field
Type of instruction
Lectures with exercises. Student projects on engineering application in their field
Exam
Exams
| Name of exam | Matrix Computations and Convex Optimization |
| Type of exam | Written or oral exam |
| ECTS | 5 |
| Assessment | Passed/Not Passed |
| Type of grading | Internal examination |
| Criteria of assessment | The criteria of assessment are stated in the Examination Policies and Procedures |
Facts about the module
| Danish title | Matriksberegning og konveks optimering |
| Module code | ESNEITB6K2 |
| Module type | Course |
| Duration | 1 semester |
| Semester | Spring
|
| ECTS | 5 |
| Language of instruction | Danish and English |
| Empty-place Scheme | Yes |
| Location of the lecture | Campus Aalborg |
| Responsible for the module |
Organisation
| Study Board | Study Board of Electronics and IT |
| Department | Department of Electronic Systems |
| Faculty | Technical Faculty of IT and Design |
