Introduction to Geometries and Mechanics
In classical mechanics, we study the evolution of a given system in configuration space. The properties of this space are described by Euclidean, projective, Riemannian, pseudo and sub-Riemannian geometries. In Hamiltonian mechanics, we have a phase space and use symplectic, Poisson, and contact geometries. To solve the equations of motion, we also use algebraic, differential, and so on other geometries. The most important and interesting mathematical models lie at the intersection of these geometric theories.
In this course we will start with Euclidean geometry and discuss general concepts such as metrics, geodesic motion, isometries, symmetries, Noether's theorem, Killing vector fields, hidden symmetries, equivalent metrics, Killing tensors, flatness and reduction of bilinear forms, orthogonal curvilinear coordinates, and so on. Then we consider some examples of constrained Hamiltonian mechanics imposing holonomic and nonholomic constraints. We then discuss the Erlangen program proposed by Klein, which is a method of characterizing geometries based on group theory and projective geometry. Some applications of Riemannian and pseudo-Riemannian geometry in mechanics have also been considered. Finally, the role of sub-Riemannian geometry in control theory is briefly discussed.
The main aim of this course is to give an overview of modern geometric methods used in various branches of classical mechanics to solve open problems. Students can discuss possible approaches to solving these open problems separately with the instructor.
In this course we will start with Euclidean geometry and discuss general concepts such as metrics, geodesic motion, isometries, symmetries, Noether's theorem, Killing vector fields, hidden symmetries, equivalent metrics, Killing tensors, flatness and reduction of bilinear forms, orthogonal curvilinear coordinates, and so on. Then we consider some examples of constrained Hamiltonian mechanics imposing holonomic and nonholomic constraints. We then discuss the Erlangen program proposed by Klein, which is a method of characterizing geometries based on group theory and projective geometry. Some applications of Riemannian and pseudo-Riemannian geometry in mechanics have also been considered. Finally, the role of sub-Riemannian geometry in control theory is briefly discussed.
The main aim of this course is to give an overview of modern geometric methods used in various branches of classical mechanics to solve open problems. Students can discuss possible approaches to solving these open problems separately with the instructor.
Lecturer
Date
10th October ~ 28th December, 2023
Location
| Weekday | Time | Venue | Online | ID | Password |
|---|---|---|---|---|---|
| Tuesday,Thursday | 09:50 - 11:25 | A3-4-101 | ZOOM 3 | 361 038 6975 | BIMSA |
Prerequisite
Knowledge of the basic concepts of classical mechanics is required. Knowledge of representation theory, metric space theory, and tensor analysis would be useful.
Reference
The material is self-sufficient but basic definitions and their discussions may be found in:
1. Agrachev A.A., Sachkov Yu.L. (2004), Control Theory from the Geometric Viewpoint.
2. Aldrovandi R., Pereira J.C. (2017), An Introduction to Geometrical Physics.
3. Bloch A.M. (2003) Nonholonomic Mechanics and Control.
4. Coxeter H. S. M. (1961), Introduction to Geometry.
5. Frolov V.P., Zelnikov A., (2015), Introduction to Black Hole Physics.
6. Hamel G. (1949), Teoretische Mechanik.
7. Klein F. (2004), Elementary Mathematics from an Advanced Standpoint: Geometry.
8. Routh E. (1884), Advanced part of a Treatise on the Dynamics of a System of Rigid Bodies.
9. Schouten J.A. (1954), Ricci-Calculus: An Introduction to Tensor Analysis and Its Geometrical Applications.
1. Agrachev A.A., Sachkov Yu.L. (2004), Control Theory from the Geometric Viewpoint.
2. Aldrovandi R., Pereira J.C. (2017), An Introduction to Geometrical Physics.
3. Bloch A.M. (2003) Nonholonomic Mechanics and Control.
4. Coxeter H. S. M. (1961), Introduction to Geometry.
5. Frolov V.P., Zelnikov A., (2015), Introduction to Black Hole Physics.
6. Hamel G. (1949), Teoretische Mechanik.
7. Klein F. (2004), Elementary Mathematics from an Advanced Standpoint: Geometry.
8. Routh E. (1884), Advanced part of a Treatise on the Dynamics of a System of Rigid Bodies.
9. Schouten J.A. (1954), Ricci-Calculus: An Introduction to Tensor Analysis and Its Geometrical Applications.
Audience
Graduate
Video Public
Yes
Notes Public
Yes
Language
English
Lecturer Intro
Andrey Tsiganov currently works at the Department of Computational Physics, Saint Petersburg State University, Russia. His main research interests are integrable and superintegrable systems in classical and quantum mechanics, nonholonomic and vakonomic mechanics, geometry and topology of dynamical systems, see profile at https://www.researchgate.net/profile/Andrey-Tsiganov. He is one of the organizers of the BIMSA Integrable System Seminar, see https://researchseminars.org/seminar/BIMSA-ISS and https://sites.google.com/view/bimsa-iss.