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Partial differential equations (PDEs): Existence and uniqueness, regularity, boundary conditions, linear and non-linear operators, stability, soliton theory, integrable PDEs, conservation laws, qualitative dynamics.

3 votes

Probabilistic solution of the porous medium equation

The processes described by Andre work by having the interaction act at the level of the mobility of the particles. There are other ways, too. One is in the work of Philipowski (see also Figalli & Phil …
Mark Peletier's user avatar
3 votes
Accepted

Doubling of variables method for parabolic equations

This paper by Felix Otto applies the method to quasilinear parabolic equations, and explains the steps in detail.
Mark Peletier's user avatar
1 vote
Accepted

A compactness result: if $f_n(u_n) \rightharpoonup w$ in $L^2(0,T;L^2)$, then $f_n(u_n) \to ...

I agree with your edited question. In fact, the information about $u_n$ seems to be unnecessary. Consider $g_n := f_n(u_n)$; then your assumptions give $g_n\rightharpoonup w$ in $L^2(0,T;L^2)$ …
Mark Peletier's user avatar
5 votes

Physical and real life interpretation of the concept of regularity used in differential equa...

An obvious other example is that of shock waves, which arise as discontinuous solutions of hyperbolic equations; in the case of acoustic waves in air, we hear the shock as a bang. More generally, eve …
Mark Peletier's user avatar
4 votes

Euler-Lagrange, Gradient Descent, Heat Equation and Image Denoising

The equation $ u_t = u_{xx} + u_{yy} $ is a gradient flow, or gradient descent, in the following sense. You should think of the equation as being placed in the space $L^2$. The Fréchèt derivative o …
Mark Peletier's user avatar