2018
DOI: 10.1080/01621459.2017.1294075
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The Bouncy Particle Sampler: A Nonreversible Rejection-Free Markov Chain Monte Carlo Method

Abstract: Many Markov chain Monte Carlo techniques currently available rely on discrete-time reversible Markov processes whose transition kernels are variations of the Metropolis-Hastings algorithm. We explore and generalize an alternative scheme recently introduced in the physics literature [27] where the target distribution is explored using a continuous-time non-reversible piecewise-deterministic Markov process. In the Metropolis-Hastings algorithm, a trial move to a region of lower target density, equivalently of hi… Show more

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Cited by 198 publications
(309 citation statements)
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“…The model code is executed: when encountering a random variable in L it is simulated from the prior, and when encountering a random variable in O a cumulative weight is updated by multiplying in the likelihood of the given value. We have then simulated from the first product (5), and assigned a weight according to the second product (6).…”
Section: Inference Methods For Programmatic Modelsmentioning
confidence: 99%
See 1 more Smart Citation
“…The model code is executed: when encountering a random variable in L it is simulated from the prior, and when encountering a random variable in O a cumulative weight is updated by multiplying in the likelihood of the given value. We have then simulated from the first product (5), and assigned a weight according to the second product (6).…”
Section: Inference Methods For Programmatic Modelsmentioning
confidence: 99%
“…Data subsampling-based algorithms [3] are becoming standard for dealing with large data sets. Monte Carlo samplers increasingly use gradient information, such as the Metropolis-adjusted Langevin algorithm (MALA) [45], HMC [36], and deterministic piecewise samplers [6,4,54]. Various methods manipulate the stream of random numbers (e.g.…”
Section: Introductionmentioning
confidence: 99%
“…For the Bouncy Particle sampler, as described by Bouchard-Côté et al (2018), the velocity set V is either the Euclidean space R d , or the unit sphere S d−1 . The associated augmented target distribution is either ρ(dx, dv) = π(dx)N (dv|0, I d ), or ρ(dx, dv) = π(dx)U S d−1 (dv), where N (·|0, I d ) represents the standard d-dimensional Gaussian distribution and U S d−1 (dv) denotes the uniform distribution over S d−1 , respectively.…”
Section: Bouncy Particle Samplermentioning
confidence: 99%
“…In recent years, non-reversible MCMC algorithms have attracted a lot of attention, because of their favourable convergence and mixing properties; the literature on the matter has rapidly become large, here we refer the reader to e.g. [14,15,2,3,7] and references therein; however, to the best of our knowledge most of the papers on non-reversible MCMC so far have tested this new class of algorithms only on relatively simple target measures. Furthermore, the performance of non-reversible algorithms has been discussed almost exclusively in the case in which the measure is supported on the whole of R N .…”
Section: Introductionmentioning
confidence: 99%