Oscillatory survival probability: Analytical and numerical study of a non-poissonian exit time

K. Dao Duc, Z. Schuss, D. Holcman

Research output: Contribution to journalArticlepeer-review

6 Scopus citations

Abstract

We consider the escape of a planar diffusion process from the domain of attraction ? of a stable focus of the drift in the limit of small diffusion. The boundary of ? is an unstable limit cycle of the drift, and the focus is close to the limit cycle. A new phenomenon of oscillatory decay of the peaks of the survival probability of the process in ? emerges for a specific distance of the focus to the boundary which depends on the amplitude of the diffusion coefficient. We show that the phenomenon is due to the complex-valued second eigenvalue λ2 (ω) of the Fokker-Planck operator with Dirichlet boundary conditions. The dominant oscillation frequency, 1/Im{λ2 (ω)}, is independent of the relative noise strength. The density of exit points on is concentrated in a small arc of ∂ω closest to the focus. When the focus approaches the boundary, the principal eigenvalue, the reciprocal of which is the mean escape time, does not necessarily decay exponentially as the amplitude of the noise strength decays. The oscillatory escape is manifested in a mathematical model of neural networks with synaptic depression. Oscillation peaks are identified in the density of the time the network spends in a specific state. This observation explains the oscillations of stochastic trajectories around a focus prior to escape and also the non-Poissonian escape times. This phenomenon has been observed and reported in experiments and simulations of neural networks.

Original languageEnglish
Pages (from-to)772-798
Number of pages27
JournalMultiscale Modeling and Simulation
Volume14
Issue number2
DOIs
StatePublished - 2016

Keywords

  • Eigenvalue
  • Exit points
  • Fokker-Planck equation
  • Limit cycle
  • Mean first passage time (MFPT)
  • Neuroscience
  • Oscillation
  • WKB asymptotics

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