Unit name | Dynamical Systems and Ergodic Theory 3 |
---|---|

Unit code | MATH36206 |

Credit points | 20 |

Level of study | H/6 |

Teaching block(s) |
Teaching Block 2 (weeks 13 - 24) |

Unit director | Dr. Jordan |

Open unit status | Not open |

Pre-requisites |
Analysis 1 (MATH11006) and Calculus 1 (MATH 11007). |

Co-requisites |
None |

School/department | School of Mathematics |

Faculty | Faculty of Science |

Unit aims

The course will provide an introduction to subject of dynamical systems, from a pure-mathematical point of view. The first part of the course will be driven by examples so that students will become familiar with various basic models of dynamical systems. We will then develop the mathematical background and the main concepts in topological dynamics, symbolic dynamics and ergodic theory. We will also show applications to other areas of pure mathematics and concrete problems as Internet search.

General Description of the Unit

Dynamical systems is an exciting and very active field in pure and applied mathematics, that involves tools and techniques from many areas such as analyses, geometry and number theory. A dynamical system can be obtained by iterating a function or letting evolve in time the solution of equation. Even if the rule of evolution is deterministic, the long term behavior of the system is often chaotic. Different branches of dynamical systems, in particular ergodic theory, provide tools to quantify this chaotic behaviour and predict it in average.

At the beginning of this lecture course we will give a strong emphasis on presenting many fundamental examples of dynamical systems, such as circle rotations, the baker map on the square and the continued fraction map. Driven by the examples, we will introduce some of the phenomena and main concepts which one is interested in studying.

In the second part of the course, we will formalize these concepts and cover the basic definitions and some fundamental theorems and results in topological dynamics, in symbolic dynamics and in particular in ergodic theory. We will give full proofs of some of the main theorems.

During the course we will also mention some applications both to other areas of mathematics, such as number theory, and to very concrete problems as Internet search engines.

Relation to Other Units

Ergodic Theory has connections with Analysis, Number theory, Statistical Mechanics and Quantum Chaos. In particular, the course will provide good background in dynamics for students interested in Statistical Mechanics (MATH 34300). Some of the topics presented have applications in Number Theory (MATH 30200) (Gauss map, Weyl’s theorem and equidistributions).

The course will provide a strong foundation from a more pure pespective for more advanced applied courses such as Applied dynamical systems (MATHM0010) and the Engineering unit on Nonlinear Dynamics and Chaos.

Metric Spaces (MATH 20200) is helpful (students will benefit from some familiarity with metric spaces) but not required: some basic notions in metric spaces and measure theory will be provided.

This unit will provide a a pure-mathematical complementary perspective to the Dynamics & Chaos units in applied dynamical systems offered by the Engineering Mathematics Department.

Additional unit information can be found at http://www.maths.bristol.ac.uk/study/undergrad/current_units/index.html

Learning Objectives

By the end of the unit the student:

- will have developed an excellent background in the area of dynamical systems,
- will be familiar with the basic concepts, results, and techniques relevant to the area,
- will have detailed knowledge of a number of fundamental examples that help clarify and motivate the main concepts in the theory,
- will understand the proofs of the fundamental theorems in the area,
- will have mastered the application of dynamical systems techniques for solving a range of standard problems,
- will have a firm foundation for further study in the area.

Transferable Skills

Assimilation of abstract ideas and reasoning in an abstract context. Problem solving and ability to work out model examples.

A standard lecture course of 30 lectures and exercises.

90% Examination and 10% Assessed Coursework

Raw scores on the examinations will be determined according to the marking scheme written on the examination paper. The marking scheme, indicating the maximum score per question, is a guide to the relative weighting of the questions. Raw scores are moderated as described in the Undergraduate Handbook.

Reading and references are available at http://www.maths.bristol.ac.uk/study/undergrad/current_units/index.html