Correlated continuous time random walks
Copyright policy )Correlated continuous time random walks
Continuous time random walks impose a random waiting time before each particle jump. Scaling limits of heavy tailed continuous time random walks are governed by fractional evolution equations. Space-fractional derivatives describe heavy tailed jumps, and the time-fractional version codes heavy tailed waiting times. This paper develops scaling limits and governing equations in the case of correlated jumps. For long-range dependent jumps, this leads to fractional Brownian motion or linear fractional stable motion, with the time parameter replaced by an inverse stable subordinator in the case of heavy tailed waiting times. These scaling limits provide an interesting class of non-Markovian, non-Gaussian self-similar processes.
13 pages
- Auburn University United States
- Michigan State University United States
- Auburn University System United States
- University of Utah United States
domain of attraction of a stable law, Functional limit theorems; invariance principles, Statistical Finance (q-fin.ST), Sums of independent random variables; random walks, 60J65, 60K99, Probability (math.PR), continuous time random walk, Quantitative Finance - Statistical Finance, Mathematics - Statistics Theory, functional limit theorem, Statistics Theory (math.ST), FOS: Economics and business, Stable stochastic processes, long-range dependence, FOS: Mathematics, Self-similar stochastic processes, Mathematics - Probability
domain of attraction of a stable law, Functional limit theorems; invariance principles, Statistical Finance (q-fin.ST), Sums of independent random variables; random walks, 60J65, 60K99, Probability (math.PR), continuous time random walk, Quantitative Finance - Statistical Finance, Mathematics - Statistics Theory, functional limit theorem, Statistics Theory (math.ST), FOS: Economics and business, Stable stochastic processes, long-range dependence, FOS: Mathematics, Self-similar stochastic processes, Mathematics - Probability
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