In this paper we study upper bounds for the density of solution of stochastic
differential equations driven by a fractional Brownian motion with Hurst
parameter H > 1/3. We show that under some geometric conditions, in the regular
case H > 1/2, the density of the solution satisfy the log-Sobolev inequality,
the Gaussian concentration inequality and admits an upper Gaussian bound. In
the rough case H > 1/3 and under the same geometric conditions, we show that
the density of the solution is smooth and admits an upper sub-Gaussian bound

Baudoin, Fabrice

Ouyang, Cheng

Tindel, Samy

English

arXiv

27 pagesIn this paper we study upper bounds for the density of solution of stochastic differential equations driven by a fractional Brownian motion with Hurst parameter H> 1/3. We show that under some geometric conditions, in the regular case H>1/2, the density of the solution satisfy the log-Sobolev inequality, the Gaussian concentration inequality and admits an upper Gaussian bound. In the rough case H>1/3 and under the same geometric conditions, we show that the density of the solution is smooth and admits an upper sub-Gaussian bound

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Upper bounds for the density of solutions of stochastic differential equations driven by fractional Brownian motions

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Upper bounds for the density of solutions of stochastic differential equations driven by fractional Brownian motions

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