250043 VU Kinetic Theory Applied to Biology (2021S)

7.00 ECTS (4.00 SWS), SPL 25 - Mathematik

Continuous assessment of course work

Moodle

Registration/Deregistration

Note: The time of your registration within the registration period has no effect on the allocation of places (no first come, first served).

Registration is open from Mo 08.02.2021 00:00 to Th 25.02.2021 17:30
Registration is open from Fr 26.02.2021 00:00 to Tu 02.03.2021 16:00
Deregistration possible until We 30.06.2021 23:59

Details

max. 25 participants

Language: English

Lecturers

Sara Merino Aceituno

Classes (iCal) - next class is marked with N

Friday 05.03. 13:15 - 16:30 Digital
Friday 19.03. 13:15 - 16:30 Digital
Friday 26.03. 13:15 - 16:30 Digital
Friday 16.04. 13:15 - 16:30 Digital
Friday 23.04. 13:15 - 16:30 Digital
Friday 30.04. 13:15 - 16:30 Digital
Friday 07.05. 13:15 - 16:30 Digital
Friday 14.05. 13:15 - 16:30 Digital
Friday 21.05. 13:15 - 16:30 Digital
Friday 28.05. 13:15 - 16:30 Digital
Friday 04.06. 13:15 - 16:30 Digital
Friday 11.06. 13:15 - 16:30 Digital
Friday 18.06. 13:15 - 16:30 Digital
Friday 25.06. 13:15 - 16:30 Digital

Information

Aims, contents and method of the course

Emergent phenomena are ubiquitous in nature: it corresponds to the appearance of large-scale structure from underlying microscopic dynamics. At the microscopic level particles or agents interact following some rules, but the macroscopic structures are not encoded directly in these rules and, therefore, it is a challenge to explain how the macroscopic or observable dynamics emerge from the microscopic ones. Examples of emergence are collective dynamics (flocks of birds, school of fish, pedestrians…), network formation (capillary formation, leaf venation, formation of gullies…), opinion dynamics, tumor growth, tissue development… Understanding emergence in science is key to explaining why observable phenomena take place. The mathematical tools to studying emergence come from kinetic theory, which originally was developed to study problems in Mathematical Physics in the field of gas dynamics. The application of these tools to explore questions coming from biology poses many new interesting challenges at the level of the modeling and mathematical analysis.

This course will be a short introduction to classical and modern techniques in kinetic theory to derive continuum equations from discrete equations.

The topics covered in this course include:
1. What is emergence and how does kinetic theory contributes to its study?
2. Discrete models or agent-based models (ordinary differential equations).
2. Mean-field limits: from discrete models to transport equations.
3. Transport equations: the case of the linear Boltzmann equation, existence of solutions.
3. Hydrodynamic limits: from transport equations to macroscopic models.
a. Boltzmann and Vlasov equations.
b. Hilbert expansion method.
c. Generalised Collision Invariant.

The course will be a combination of theory and exercises done during the class. Articles will be distributed and worked in class in which the theory learned will be applied. The active participation of students during class is expected.

Appropriate breaks will be taken during the class.

Assessment and permitted materials

Minimum requirements and assessment criteria

- Students must attend all classes, only a maximum of 3 can be missed.
- Students must participate during the class activities and do their homework, like solving exercises or commenting on reading articles. Small oral presentations on solutions may be requested.
- Students must do a project that will include a report and a discussion with the lecturer.

Examination topics

Reading list

Association in the course directory

MBIV; MAMV;

Last modified: Fr 12.05.2023 00:21