6533b851fe1ef96bd12a8e3a

RESEARCH PRODUCT

Ideal and physical barrier problems for non-linear systems driven by normal and Poissonian white noise via path integral method

Mario Di PaolaChristian Bucher

subject

Monte Carlo methodMarkov processProbability density function02 engineering and technologyWhite noise01 natural sciencesBarrier crossingsymbols.namesake0203 mechanical engineeringStructural reliability0103 physical sciencesBoundary value problem010301 acousticsMathematicsApplied MathematicsMechanical EngineeringMathematical analysisFokker-Planck equationWhite noisePath integrationNonlinear system020303 mechanical engineering & transportsMechanics of MaterialsPath integral formulationsymbolsFokker–Planck equationRandom vibration

description

Abstract In this paper, the probability density evolution of Markov processes is analyzed for a class of barrier problems specified in terms of certain boundary conditions. The standard case of computing the probability density of the response is associated with natural boundary conditions, and the first passage problem is associated with absorbing boundaries. In contrast, herein we consider the more general case of partially reflecting boundaries and the effect of these boundaries on the probability density of the response. In fact, both standard cases can be considered special cases of the general problem. We provide solutions by means of the path integral method for half- and single-degree-of-freedom systems for both normal and Poissonian white noise. Emphasis is put on the considerations of the yielding barrier which is expressed in terms of non-reflecting (but not absorbing) boundary conditions. Comparison with Monte Carlo simulation demonstrates the excellent accuracy of the proposed method.

yearjournalcountryeditionlanguage
2016-05-01
10.1016/j.ijnonlinmec.2016.01.008http://hdl.handle.net/10447/193543