We develop a class of averaging lemmas for stochastic kinetic equations. The
velocity is multiplied by a white noise which produces a remarkable change in
time scale. Compared to the deterministic case and as far as we work in $L^2$,
the nature of regularity on averages is not changed in this stochastic kinetic
equation and stays in the range of fractional Sobolev spaces at the price of an
additional expectation. However all the exponents are changed; either time
decay rates are slower (when the right hand side belongs to $L^2$), or
regularity is better when the right hand side contains derivatives. These
changes originate from a different space/time scaling in the deterministic and
stochastic cases. Our motivation comes from scalar conservation laws with
stochastic fluxes where the structure under consideration arises naturally
through the kinetic formulation of scalar conservation laws

Lions, Pierre-Louis

Perthame, Benoit

Souganidis, Panagiotis E.

English

arXiv

International audienceWe develop a class of averaging lemmas for stochastic kinetic equations. The velocity is multiplied by a white noise which produces a remarkable change in time scale. Compared to the deterministic case and as far as we work in $L^2$, the nature of regularity on averages is not changed in this stochastic kinetic equation and stays in the range of fractional Sobolev spaces at the price of an additional expectation. However all the exponents are changed; either time decay rates are slower (when the right hand side belongs to $L^2$), or regularity is better when the right hand side contains derivatives. These changes originate from a different space/time scaling in the deterministic and stochastic cases. Our motivation comes from scalar conservation laws with stochastic fluxes where the structure under consideration arises naturally through the kinetic formulation of scalar conservation laws

Lions, Pierre Louis

Perthame, Benoît

Hal-Diderot

Stochastic averaging lemmas for kinetic equations

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We develop a class of averaging lemmas for stochastic kinetic equations. The velocity is multiplied by a white noise which produces a remarkable change in time scale. Compared to the deterministic case and as far as we work in $L^2$, the nature of regularity on averages is not changed in this stochastic kinetic equation and stays in the range of fractional Sobolev spaces at the price of an additional expectation. However all the exponents are changed; either time decay rates are slower (when the right hand side belongs to $L^2$), or regularity is better when the right hand side contains derivatives. These changes originate from a different space/time scaling in the deterministic and stochastic cases. Our motivation comes from scalar conservation laws with stochastic fluxes where the structure under consideration arises naturally through the kinetic formulation of scalar conservation laws.ou

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Stochastic averaging lemmas for kinetic equations

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Hal-Diderot

INRIA a CCSD electronic archive server

Base de publications de l'université Paris-Dauphine

Numérisation de Documents Anciens Mathématiques