English

On optimal tempered L\'evy flight foraging

Statistical Mechanics 2018-06-05 v1 Biological Physics

Abstract

Optimal random foraging strategy has gained increasing concentrations. It is shown that L\'evy flight is more efficient compared with the Brownian motion when the targets are sparse. However, standard L\'evy flight generally cannot be followed in practice. In this paper, we assume that each flight of the forager is possibly interrupted by some uncertain factors, such as obstacles on the flight direction, natural enemies in the vision distance, and restrictions in the energy storage for each flight, and introduce the tempered L\'evy distribution p(l)eρllμp(l)\sim {\rm e}^{-\rho l}l^{-\mu}. It is validated by both theoretical analyses and simulation results that a higher searching efficiency can be derived when a smaller ρ\rho or μ\mu is chosen. Moreover, by taking the flight time as the waiting time, the master equation of the random searching procedure can be obtained. Interestingly, we build two different types of master equations: one is the standard diffusion equation and the other one is the tempered fractional diffusion equation.

Cite

@article{arxiv.1806.00909,
  title  = {On optimal tempered L\'evy flight foraging},
  author = {Yuquan Chen and Derek Hollenbeck and Yong Wang and YangQuan Chen},
  journal= {arXiv preprint arXiv:1806.00909},
  year   = {2018}
}

Comments

21 pages, 9 figures

R2 v1 2026-06-23T02:17:38.660Z