Persistence of a Continuous Stochastic Process with Discrete-Time Sampling: Non-Markov Processes
Abstract
We consider the problem of `discrete-time persistence', which deals with the zero-crossings of a continuous stochastic process, X(T), measured at discrete times, T = n( T). For a Gaussian Stationary Process the persistence (no crossing) probability decays as exp(-θD T) = [(a)]n for large n, where a = [-( T)/2], and the discrete persistence exponent, θD, is given by θD = ()/2(a). Using the `Independent Interval Approximation', we show how θD varies with ( T) for small ( T) and conclude that experimental measurements of persistence for smooth processes, such as diffusion, are less sensitive to the effects of discrete sampling than measurements of a randomly accelerated particle or random walker. We extend the matrix method developed by us previously [Phys. Rev. E 64, 015151(R) (2001)] to determine (a) for a two-dimensional random walk and the one-dimensional random acceleration problem. We also consider `alternating persistence', which corresponds to a < 0, and calculate (a) for this case.
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