Stochastic calculus for uncoupled continuous-time random walks

Abstract: The continuous-time random walk (CTRW) is a pure-jump stochastic process with several applications in physics, but also in insurance, finance and economics. A definition is given for a class of stochastic integrals driven by a CTRW, that includes the Itō and Stratonovich cases. An uncoupled CTRW with zero-mean jumps is a martingale. It is proved that, as a consequence of the martingale transform theorem, if the CTRW is a martingale, the Itō integral is a martingale too. It is shown how the definition of the st… Show more

“…Some results highlighted here were already published in [8]. However, the main focus of that paper was defining and studying the properties of stochastic integrals driven by pure jump processes.…”

On the convergence of quadratic variation for compound fractional Poisson processes

“…Some results highlighted here were already published in [8]. However, the main focus of that paper was defining and studying the properties of stochastic integrals driven by pure jump processes.…”

On the convergence of quadratic variation for compound fractional Poisson processes

“…The properties of the corresponding Master Equation (ME) lead to name such diffusion as Erdélyi-Kober fractional diffusion [50,51,52]. Actually, the M-Wright function was also used as a non-Markovian model to generalize the evolution in time of the radius of a premixed flame ball in fractional diffusive media [49,50] and it has emerged to be related to the quadratic variation for compound renewal processes [56] whose convergence is important for stochastic integrals driven by a CTRW [11].…”

The M-Wright function as a generalization of the Gaussian density for fractional diffusion processes

“…[2,3]), the probability density P (x, t) of the particle position X(t) depends only on the joint probability density of waiting time and jump length. Unfortunately, even in the simplest (decoupled) case when the joint density is a product of waiting-time density p(τ ) and jump-length density w(ξ), the representation of P (x, t) in terms of special functions is known in a few cases [14][15][16]. In contrast, the long-time behavior of P (x, t) that determines the diffusion and transport properties of walking particles is studied analytically in much more detail [17][18][19][20][21].…”

Limiting distributions of continuous-time random walks with superheavy-tailed waiting times