Nonlinear Fokker-Planck equations as smooth Hilbertian gradient flows
Abstract
Under suitable assumptions on β:R\!\!R, \,D:Rd\!\!Rd and b:Rd\!\!R, the nonlinear Fokker-Planck equation ut-β(u)+ div(Db(u)u)=0, in (0,∞)×Rd where D=-∇, can be identified as a smooth gradient flow d+dt\,u(t)+∇ Eu(t)=0, ∀ t>0. Here, E:P* L∞(Rd) is the energy function associated to the equation, where P* is a certain convex subset of the space of probability densities. P* is invariant under the flow and ∇ Eu is the gradient of E, that is, the tangent vector field to P at u defined by <∇ Eu,zu>u= diff\,Eu· zu for all vector fields zu on P*, where <·,·>u is a scalar product on a suitable tangent space Tu(P*)⊂D'(Rd).
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