Stochastic resetting with refractory periods: pathway formulation and exact results

García-Valladares, G; Gupta, D; Prados, A; Plata, C A

doi:10.1088/1402-4896/ad317b

Phys. Scr.

2024

DOI: 10.1088/1402-4896/ad317b

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Stochastic resetting with refractory periods: pathway formulation and exact results

G García-Valladares,

D Gupta,

A Prados

et al.

Abstract: We look into the problem of stochastic resetting with refractory periods. The model dynamics comprises diffusive and motionless phases. The diffusive phase ends at random time instants, at which the system is reset to a given position---where the system remains at rest for a random time interval, termed the refractory period. A pathway formulation is introduced to derive exact analytical results for the relevant observables in a broad framework, with the resetting time and the refractory period following arbit… Show more

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2024

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Cited by 3 publications

References 70 publications

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Emerging cost-time Pareto front for diffusion with stochastic return

Singh

2024

New J. Phys.

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Resetting, in which a system is regularly returned to a given state after a fixed or random duration, has become a useful strategy to optimize the search performance of a system. While earlier theoretical frameworks focused on instantaneous resetting, wherein the system is directly teleported to a given state, there is a growing interest in physical resetting mechanisms that involve a finite return time. However employing such a mechanism involves cost and the effect of this cost on the search time remains largely unexplored. Yet answering this is important in order to design cost-efficient resetting strategies. Motivated from this, we present a thermodynamic analysis of a diffusing particle whose position is intermittently reset to a specific site by employinga stochastic return protocol with external confining trap. We show for a family of potentials $U_R(x) \sim |x|^{m}$ with $m>0$, it is possible to find optimal potential shape that minimises the expected first-passage time for a given value of the thermodynamic cost, i.e mean work. By varying this value, we then obtain the Pareto optimal front, and demonstrate a trade-off relation between the first-passage time and the work done.

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Emerging cost-time Pareto front for diffusion with stochastic return

Singh

2024

New J. Phys.

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Partial stochastic resetting with refractory periods

Olsen,

Löwen

2024

J. Phys. A: Math. Theor.

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The effect of refractory periods in partial resetting processes is studied. Under Poissonian partial resets, a state variable jumps to a value closer to the origin by a fixed fraction at constant rate, $x\to a x$. Following each reset, a stationary refractory period of arbitrary duration takes place. We derive an exact closed-form expression for the propagator in Fourier-Laplace space, which shows rich dynamical features such as connections not only to other resetting schemes but also to intermittent motion. For diffusive processes, we use the propagator to derive exact expressions for time dependent moments of $x$ at all orders. At late times the system reaches a non-equilibrium steady state which takes the form of a mixture distribution that splits the system into two subpopulations; trajectories that at any given time in the stationary regime find themselves in the freely evolving phase, and those that are in the refractory phase. In contrast to conventional resetting, partial resets give rise to non-trivial steady states even for the refractory subpopulation. Moments and cumulants associated with the steady state density are studied, and we show that a universal optimum for the kurtosis can be found as a function of mean refractory time, determined solely by the strength of the resetting and the mean inter-reset time. The presented results could be of relevance to growth-collapse processes with periods of inactivity following a collapse.

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Active motion can be beneficial for target search with resetting in a thermal environment

Pal,

Park,

Pal

et al. 2024

Phys. Rev. E

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Stochastic resetting with refractory periods: pathway formulation and exact results

Cited by 3 publications

References 70 publications

Emerging cost-time Pareto front for diffusion with stochastic return

Emerging cost-time Pareto front for diffusion with stochastic return

Partial stochastic resetting with refractory periods

Active motion can be beneficial for target search with resetting in a thermal environment

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