Safety of particle filters: Some results on the time evolution of particle filter estimates
Abstract
Particle filters (PFs) form a class of Monte Carlo algorithms that propagate over time a set of N≥ 1 particles which can be used to estimate, in an online fashion, the sequence of filtering distributions (ηt)t≥ 1 defined by a state-space model. Despite the popularity of PFs, the study of the time evolution of their estimates has received barely any attention in the literature. Denoting by (ηtN)t≥ 1 the PF estimate of (ηt)t≥ 1 and letting ∈ (0,1/2), in this work we first show that for any number of particles N it holds that, with probability one, we have \|ηtN- ηt\|≥ for infinitely many time instants t≥ 1, with \|·\| the Kolmogorov distance between probability distributions. Considering a simple filtering problem we then provide reassuring results concerning the ability of PFs to estimate jointly a finite set \ηt\t=1T of filtering distributions by studying the probability P(t∈\1,…,T\\|ηtN-ηt\|≥ ). Finally, on the same toy filtering problem, we prove that sequential quasi-Monte Carlo, a randomized quasi-Monte Carlo version of PF algorithms, offers greater safety guarantees than PFs in the sense that, for this algorithm, it holds that N→∞t≥ 1\|ηtN-ηt\|=0 with probability one.
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