Course detail

Geometric Control Theory

FSI-9GTRAcad. year: 2021/2022

Advanced Differential Geometry and Representation Theory in the theory Optimal Transport of Non-Holonomic Systems. Algebraic view of the dynamic systems.

Language of instruction

Czech

Mode of study

Not applicable.

Learning outcomes of the course unit

Students will learn to use advanced parts of differential geometry and representation theory. For a specific mechanism: the construction of kinematic chain, the solution of differential kinematics, design of optimal trajectory.

Prerequisites

The knowledge of mathematics gained within the bachelor's study programme.

Co-requisites

Not applicable.

Planned learning activities and teaching methods

The course is taught through lectures explaining the basic principles and theory of the discipline.

Assesment methods and criteria linked to learning outcomes

The course is finished by written and oral examination. The written part is 80% and the oral part 20% of the grade.

Course curriculum

Not applicable.

Work placements

Not applicable.

Aims

Building the basics of geometric control theory. Ability to apply theory to engineering problems.

Specification of controlled education, way of implementation and compensation for absences

Výuka se odehrává formou přednášky a není kontrolovaná

Recommended optional programme components

Not applicable.

Prerequisites and corequisites

Not applicable.

Basic literature

Enrico Le Donne, Lecture notes on sub-Riemannian geometry, University of Jyväskylä (EN)
L. Zexiang, S. Sastry , R. M. Murray, A Mathematical Introduction to Robotic Manipulation. CRC Press, 1994. (EN)
Y.L. Sachkov. Control theory on lie groups. J Math Sci, 156(3):381--439, 2009. (EN)

Recommended reading

Not applicable.

Classification of course in study plans

  • Programme D-APM-P Doctoral 1 year of study, winter semester, recommended course
  • Programme D-APM-K Doctoral 1 year of study, winter semester, recommended course

Type of course unit

 

Lecture

20 hod., optionally

Teacher / Lecturer

Syllabus

1. Lie algebras, definitions and basic concepts, examples (orthogonal, special, Heisenberg, etc. ), adjoint representation, semi-simple, solvable and nilpotent Lie algebras.

2. Algebra of controllability, configuration space, non-homonomous conditions, differential kinematics, Pffaf's system, vector fields and bracket.

3. Nilpotent approximations (symbols), definitions and basic properties, adapted and privileged coordinates, Bellaiche's Algorithm.

4. Lie groups. definitions, examples (special, orthogonal, spin, etc.), Lie algebra as the tangent space of Lie groups.

5. Leftinvariant vector fields, definition, Lie algebra of left-vector vector fields, flows of vector fields, a group structure under of nilpotent Lie algebras.

6. Sub - Riemanian (sR) geometry, distribution, sR-metric, horizontal curves.

7. Minimal curves (local extremals), PMP for nilpotent approximations, normal and abnormal extremals, sR-Hamiltonian

8. Heisenberg geometry, Heisenberg's group and algebra, description of the mechanism known as dubin car.

9. Other Structures on Heisenberg geometry. Overview of Heisenberg Geometry, Lagrange and CR Geometry. Infinitesimal automorphisms.

10. Conjunction points. Fixed points of infinitesimal automorphisms. Heisenberg's apple.