Caput Dynamical Systems and Chaos
Faculteit  Science and Engineering 
Jaar  2020/21 
Vakcode  WMMA00405 
Vaknaam  Caput Dynamical Systems and Chaos 
Niveau(s)  master 
Voertaal  Engels 
Periode  semester I a 
ECTS  5 
Rooster  rooster.rug.nl 
Uitgebreide vaknaam  Caput Dynamical Systems and Chaos  
Leerdoelen  At the end of the course, the student is able to: 1. reproduce key properties and phenomenology of standard examples of dynamical systems, such as "the doubling map", "the Henon map", "the horseshoe map", "the solenoid", "circle maps", and relate the qualitative features of such examples to more complex systems. 2. apply key concepts, such as "Poincare maps", "suspensions", "symbolic dynamics", "conjugation", "multiperiodic dynamics", "chaotic dynamics", "dispersion exponents", "persistence of dynamical properties", "attractors", and "structural stability'' to concrete examples of dynamical systems. 3. Explain the difference between a "regular" and a "singular perturbation", in particular in the context of ordinary differential equations. 4. Apply the concept of "normal hyperbolicity" to concrete examples of dynamical systems. 5. Apply the "geometric desingularization technique" via blowup to concrete examples of dynamical systems. 

Omschrijving  Dynamical systems theory concerns the question of how deterministic systems evolve in time. This first of all concerns the longterm behaviour of systems which includes stationary, periodic, multiperiodic, and chaotic dynamics, but also transient behaviour is of interest. Moreover bifurcations or transitions between asymptotic states  in particular transitions between regular and chaotic motions  under variation of parameters are of great importance. Special stationary solutions or more generally invariant manifolds can also form the organizing centers for the dynamics in the state space of a dynamical system. Applications of dynamical systems theory range from molecular dynamics to celestial mechanics and extend to the life sciences, climate science, and many other fields. The first half of the course will consist of lectures based on the text book by Broer and Takens, which will provide a solid background. The second half of the course is devoted to studying a topic in contemporary research on dynamical systems and their applications. A trending and challenging issue in dynamical systems are singular perturbation problems. Here we will be motivated by singular perturbations that arise when considering dynamics with multiple time scales. Mathematical models involving multiple time scales are relevant in neuroscience, biology, engineering, economy, among many others. In the second half of this course we will provide the basic theory of deterministic dynamical systems with two or more time scales, and learn to distinguish regular from singular problems. We will also discuss a geometric technique that is suitable to analyse such singular problems. This part of the course is based on the book by Kuehn. 

Uren per week  
Onderwijsvorm 
Hoorcollege (LC), Opdracht (ASM)
(The students will give presentations during the tutorials) 

Toetsvorm 
Opdracht (AST)
(The final grade is computed as (A1 + A2) / 2, where A1 and A2, are the grades for the two takehome exam assignments.) 

Vaksoort  master  
Coördinator  dr. A.E. Sterk  
Docent(en)  dr. H. Jardon Kojakhmetov ,dr. A.E. Sterk  
Verplichte literatuur 


Entreevoorwaarden  The course unit assumes prior knowledge acquired from an introductory course to dynamical systems theory like the compulsory course Dynamical Systems in the bachelor curriculum.  
Opmerkingen  The material will be tailormade for the projects to be carried out in groups. This course was registered last year with course code WMMA16003 

Opgenomen in 
