In this paper, by using a Fourier analytic approach, we investigate sample path properties of the fractional derivatives of multifractional Brownian motion local times. We also show that those additive functionals satisfy a property of local asymptotic self-similarity. As a consequence, we derive some local limit theorems for the occupation time of multifractional Brownian motion in the space of continuous functions.In this paper, by using a Fourier analytic approach, we investigate sample path properties of the fractional derivatives of multifractional Brownian motion local times. We also show that those additive functionals satisfy a property of local asymptotic self-similarity. As a consequence, we derive some local limit theorems ...
Gaussian process, fractional Brownian motion, multifractional Brownian motion, Hölder regularity, po...
To appear in Stochastic Processes and their Applications 124 (2014) 678-708International audienceSto...
Denote by H(t) = (H1(t),...,HN(t)) a function in t ∈ RN+ with values in (0,1)N. Let {BH(t)(t)} = {B...
AbstractThe multifractional Brownian motion (MBM) processes are locally self-similar Gaussian proces...
Estimates for the local and uniform moduli of continuity of the local time of the multifractional Br...
In the paper, we study the existence of the local nondeterminism and the joint continuity of the loc...
36 pagesInternational audienceMultifractional Brownian motion is an extension of the well-known frac...
International audienceMultifractional Brownian motion is an extension of the well-known fractional B...
We prove a general functional limit theorem for multiparameterfractional Brownian motion. The functi...
International audienceMultifractional processes are stochastic processes with non-stationary increme...
We extend and adapt a class of estimators of the parameter H of the fractional Brownian motion in or...
In this article we will present a new perspective on the variable order fractional calculus, which a...
AbstractRecently, N. Kôno gave a limit theorem for occupation times of fractional Brownian motion, w...
AbstractA general approximation model for the continuous additive functionals of the multidimensiona...
AbstractThe generalized multifractional Brownian motion (GMBM) is a continuous Gaussian process that...
Gaussian process, fractional Brownian motion, multifractional Brownian motion, Hölder regularity, po...
To appear in Stochastic Processes and their Applications 124 (2014) 678-708International audienceSto...
Denote by H(t) = (H1(t),...,HN(t)) a function in t ∈ RN+ with values in (0,1)N. Let {BH(t)(t)} = {B...
AbstractThe multifractional Brownian motion (MBM) processes are locally self-similar Gaussian proces...
Estimates for the local and uniform moduli of continuity of the local time of the multifractional Br...
In the paper, we study the existence of the local nondeterminism and the joint continuity of the loc...
36 pagesInternational audienceMultifractional Brownian motion is an extension of the well-known frac...
International audienceMultifractional Brownian motion is an extension of the well-known fractional B...
We prove a general functional limit theorem for multiparameterfractional Brownian motion. The functi...
International audienceMultifractional processes are stochastic processes with non-stationary increme...
We extend and adapt a class of estimators of the parameter H of the fractional Brownian motion in or...
In this article we will present a new perspective on the variable order fractional calculus, which a...
AbstractRecently, N. Kôno gave a limit theorem for occupation times of fractional Brownian motion, w...
AbstractA general approximation model for the continuous additive functionals of the multidimensiona...
AbstractThe generalized multifractional Brownian motion (GMBM) is a continuous Gaussian process that...
Gaussian process, fractional Brownian motion, multifractional Brownian motion, Hölder regularity, po...
To appear in Stochastic Processes and their Applications 124 (2014) 678-708International audienceSto...
Denote by H(t) = (H1(t),...,HN(t)) a function in t ∈ RN+ with values in (0,1)N. Let {BH(t)(t)} = {B...