Falcón-Cortés Andrea, Boyer Denis, Giuggioli Luca, Majumdar Satya N
Instituto de Física, Universidad Nacional Autónoma de México, Ciudad de México 04510, Mexico.
Bristol Centre for Complexity Sciences, Department of Engineering Mathematics and School of Biological Sciences, University of Bristol, Bristol BS8 1UB, United Kingdom.
Phys Rev Lett. 2017 Oct 6;119(14):140603. doi: 10.1103/PhysRevLett.119.140603. Epub 2017 Oct 4.
We solve an adaptive search model where a random walker or Lévy flight stochastically resets to previously visited sites on a d-dimensional lattice containing one trapping site. Because of reinforcement, a phase transition occurs when the resetting rate crosses a threshold above which nondiffusive stationary states emerge, localized around the inhomogeneity. The threshold depends on the trapping strength and on the walker's return probability in the memoryless case. The transition belongs to the same class as the self-consistent theory of Anderson localization. These results show that similarly to many living organisms and unlike the well-studied Markovian walks, non-Markov movement processes can allow agents to learn about their environment and promise to bring adaptive solutions in search tasks.
我们求解了一个自适应搜索模型,其中随机游走者或 Lévy 飞行在包含一个陷阱位点的 d 维晶格上随机重置到先前访问过的位点。由于强化作用,当重置率超过一个阈值时会发生相变,超过该阈值会出现非扩散稳态,这些稳态围绕不均匀性局部化。该阈值取决于陷阱强度以及在无记忆情况下游走者的返回概率。该转变与安德森局域化的自洽理论属于同一类别。这些结果表明,与许多生物体类似且与经过充分研究的马尔可夫游走不同,非马尔可夫运动过程可以使主体了解其环境,并有望在搜索任务中带来自适应解决方案。
