Numerical methods in physics
Master PhysiqueParcours Physics of Quantum and Soft Condensed Matter
ComposanteFaculté de physique et ingénierie
Catalogue2026-2027
Description
The objective is to introduce machine learning approaches and numerical methods able to treat various physical questions.
Compétences visées
• Applying knowledge in physics;
• Apply methods from mathematics and digital technology;
• Produce a critical analysis, with hindsight and perspective;
• Interact with colleagues in physics and other disciplines;
• Research a physics topic using specialised resources;
• Communicate in writing and orally, including in English;
• Respect ethical, professional and environmental principles in the practice of physics.
Syllabus
- Introduction to machine learning
- Supervised learning:
- Classification: support vector machine
- Classification/regression: decision tree
- Unsupervised learning:
- Clustering methods
- dimensional reduction
- Unified view of classical methods (FD, FE). Application to Helmholtz equation.
- Tensor method for large dimensional Schrodinger equation.
- Neural networks bases methods. Application to Grad-Shafranov PDE
- Eulerian methods. Applicationt to Radiative transfer
- Semi-Lagrangian methods. Application to linear Vlasov equation.
- Introduction to physical and data driven model reduction. Applications to previous PDE.