Random walk of multiple agents in a confined space

Authors

Jen-Jen Manuel National Institute of Physics, University of the Philippines Diliman
Christopher Monterola National Institute of Physics, University of the Philippines Diliman

Abstract

While most literature on random walk involves unconfined motion of a single random walker, self-organization of real systems is normally driven by space-confined motion of a collection of agents. Here, we study the effect of confinement and density of N randomly moving agents in the time evolution of the mean squared distance R (T) = < r² >, where r is the displacement from the initial location. The motion of agents in a square lattice of dimension L x L follows Von-Neumann type of neighborhood. We establish the existence of a universal saturation point equal to Rsat = R(T → ∞) ~ 0.33 L² , and provide an analytic approximation for this limit. The saturation is shown to be independent of the lattice size and the density ρ = N/L² of agents that are moving simultaneously. The approach to the equilibrium however is shown to evolve accurately following R(T) = Rsat(1 - e⁻ᵇᵗ), where b is proportional to L² (1 - ρ).

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Issue

2010: Proceedings of the 28th Samahang Pisika ng Pilipinas Physics Congress

Article ID

SPP-2010-PA-16

Section

Poster Session PA

Published

2010-10-25

How to Cite

[1]

J-J Manuel and C Monterola, Random walk of multiple agents in a confined space, Proceedings of the Samahang Pisika ng Pilipinas 28, SPP-2010-PA-16 (2010). URL: https://proceedings.spp-online.org/article/view/SPP-2010-PA-16.