Non-symmetric intrinsic Hopf-Lax semigroup vs. intrinsic Lagrangian
Abstract
In this paper, we analyze the 'symmetrized' of the intrinsic Hopf-Lax semigroup introduced by the author in the context of the intrinsically Lipschitz sections in the setting of metric spaces. Indeed, in the usual case, we have that d(x,y) =d(y,x) for any point x and y belong to the metric space X; on the other hand, in our intrinsic context, we have that d(f(x),π-1 (y)) d(f(y),π-1 (x)), for every x,y ∈ X. Therefore, it is not trivial that we get the same result obtained for the "classical" intrinsic Hopf-Lax semigroup, i.e., the 'symmetrized' Hopf-Lax semigroup is a subsolution of Hamilton-Jacobi type equation. Here, an important observation is that f is just a continuous section of a quotient map π and it can not intrinsic Lipschitz. However, following Evans, the main result of this note is to show that the "new" intrinsic Hopf-Lax semigroup satisfies a suitable variational problem where the functional contained an intrinsic Lagrangian. Hence, we also define and prove some basic properties of the intrinsic Fenchel-Legendre transform of this intrinsic Lagrangian that depends on a continuous section of π.
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