Volume 52 Issue 1
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Li Y, Zhao F, Liu X B. On the exit behaviors of non-Gaussian stochastic dynamical systems based on large deviation theory. Advances in Mechanics, 2022, 52(1): 79-116 doi: 10.6052/1000-0992-21-033
Citation: Li Y, Zhao F, Liu X B. On the exit behaviors of non-Gaussian stochastic dynamical systems based on large deviation theory. Advances in Mechanics, 2022, 52(1): 79-116 doi: 10.6052/1000-0992-21-033

On the exit behaviors of non-Gaussian stochastic dynamical systems based on large deviation theory

doi: 10.6052/1000-0992-21-033
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  • Corresponding author: xbliu@nuaa.edu.cn
  • Received Date: 2021-06-10
  • Accepted Date: 2021-09-06
  • Available Online: 2021-09-17
  • Publish Date: 2022-03-25
  • This paper introduces the basic ideas of large deviation theory and its applications in the study of exit problems of non-Gaussian stochastic dynamical systems. According to different types of non-Gaussian noise, the main research methods and recent progresses of exit problems are reviewed for stochastic hybrid systems, stochastic dynamical systems with exponentially light jump fluctuations, and stochastic systems with $\alpha $-stable Lévy noises. For the stochastic hybrid systems, the quasi-steady-state diffusion approximation which is approximated by stochastic differential equations, the WKB approximation for computing quasi-potential and optimal exit paths, the research on detailed balance conditions, and progresses in exit problems of the simplified version of stochastic hybrid systems (i.e. birth-and-death processes) are introduced. For the stochastic dynamical systems driven by the exponential light jump processes, the establishment of the functional extremum problems of large deviation principle and moderate deviation principle, the definition of the quasi-potential concept and the estimation of the mean exit time are discussed. For stochastic systems with stable Lévy noises, the theoretical and numerical methods for calculating the mean exit time and exit probability, and Onsager-Machlup theory, machine learning method, maximum likelihood method and data-driven method for computing the optimal exit paths are illustrated. Finally, some open problems related to the exit phenomena of non-Gaussian stochastic dynamical systems are given.

     

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