Difference between revisions of "MAT4143"

Complex Analysis Part I

• Definition and algebraic properties of complex numbers, Riemann Sphere, Holomorphic functions and conformal mappings

Complex Analysis Part II

Integrals in the Complex Plane, Cauchy's theorem, Calculus of Residues

Complex Analysis Part III

Multivariable Calculus, Chain Rule

• Harmonic functions and Poisson's formula

Tensor Calculus Basics I

• Using indices in three-dimensional cartesian vector analysis, deriving vector identities using index calculus, divergence, grad and curl in index notation, divergence and Stokes' theorem.

Tensor Caluclus Basics II

• Manifolds and coordinate transformations, vector fields, Riemannian geometry, covariant derivatives and Christoffel symbols

Applied Functional Analysis Part I

• Hilbert spaces and inner products, orthogonality and completeness.

Applied Functional Analysis Part II

• Operators in Hilbert spaces, eigenvalue problem, self-adjointness and spectral properties

Applied Functional Analysis Part III

• Examples of Hilbert spaces in quantum mechanics, standard examples such as potential wells and harmonic oscillator

Overview about ordinary differential equations I

• systems of nonlinear/linear equations, basic existence and uniqueness theorems

Overview about ordinary differential equations II

Differentiation of integrals with respect to parameter

• phase-plane, linearization, stability, chaos

PDE's of Mathematical Physics

• standard examples, qualitative properties, conservation laws

Introduction to Lie Groups and Symmetries I

• Definition of a Lie group and examples, commutators and Lie brackets, Lie algebras

Introduction to Lie Groups and Symmetries II

• Exponential maps, applications of Lie groups to differential equations, Noether's theorem

KdV equation, completely integrable systems