On the entropic convergence for piecewise deterministic samplers: speedup and obstruction
Pith reviewed 2026-06-25 19:37 UTC · model grok-4.3
The pith
RHMC achieves the diffusive-to-ballistic speedup in relative entropy while BPS and ZZS lose all exponential entropy convergence even on Gaussians.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
The diffusive-to-ballistic speedup holds in relative entropy for RHMC. For BPS and ZZS, exponential convergence in relative entropy fails even for the standard Gaussian target.
What carries the argument
The diffusive-to-ballistic speedup, which quadratically improves convergence rates with suitable parameters relative to overdamped Langevin, carries the positive result for RHMC while the failure of entropy dissipation under the jump mechanisms obstructs it for BPS and ZZS.
If this is right
- RHMC admits parameter choices that yield quadratically faster entropy convergence than overdamped Langevin.
- BPS and ZZS require convergence analyses that do not rely on exponential entropy decay.
- The choice among piecewise deterministic samplers affects whether entropy-based performance guarantees are available.
- Log-concavity is not sufficient by itself to guarantee entropy speedup across all such samplers.
Where Pith is reading between the lines
- The jump mechanisms in BPS and ZZS may prevent the entropy dissipation that continuous Hamiltonian flow preserves.
- When entropy bounds matter for downstream tasks, RHMC may be preferable to the other two samplers.
- Hybrid constructions that retain ballistic motion while altering jump rules could be tested for restored entropy convergence.
Load-bearing premise
The log-concavity of the target together with the standard generator and jump mechanisms of each process are required for both the speedup and the obstruction.
What would settle it
A direct computation or simulation of the relative entropy along the BPS trajectory on the standard Gaussian that exhibits exponential decay at a dimension-independent positive rate would refute the obstruction result.
read the original abstract
For piecewise deterministic samplers such as Randomized Hamiltonian Monte Carlo (RHMC), Bouncy Particle Sampler (BPS) or Zig-Zag Process (ZZP), long-time exponential convergence rates have been established in previous works using Harris or $L^2$ hypocoercivity approaches. In particular, in the $L^2$ framework, a so-called \emph{diffusive-to-ballistic} speedup was known for log-concave targets, according to which the convergence rates of these samplers, with suitable parameters, are quadratically improved with respect to the standard overdamped Langevin diffusion process. A recent work by Jianfeng Lu showed that this speedup also holds for the kinetic Langevin diffusion process when the convergence is stated in terms of relative entropy, raising the question whether this also holds for piecewise deterministic samplers. The present work provides a positive and a negative answer to this: first, we show that the speedup holds in entropy for RHMC; second, we show that for BPS or ZZS, even for a standard Gaussian target, a similar result cannot hold, and even that exponential convergence (at any rate) in entropy fails.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript establishes a positive result that the diffusive-to-ballistic speedup (quadratic improvement over overdamped Langevin) previously known in L² for log-concave targets extends to relative entropy for Randomized Hamiltonian Monte Carlo (RHMC). It also establishes a negative result: for the Bouncy Particle Sampler (BPS) and Zig-Zag Sampler (ZZS), exponential convergence in relative entropy fails at any rate, even when the target is the standard Gaussian.
Significance. If the derivations hold, the work supplies a precise distinction among PDMP samplers regarding entropy dissipation, extending the L²/Harris hypocoercivity literature and the recent entropy result for kinetic Langevin. The combination of a positive speedup for RHMC and an explicit obstruction for BPS/ZZS is a substantive clarification for the design of entropy-based analyses of piecewise deterministic processes.
minor comments (3)
- [§2] The abstract and introduction reference the standard generators and jump mechanisms of RHMC, BPS, and ZZS; the manuscript should include a short self-contained paragraph (perhaps §2) recalling the precise infinitesimal generators and the parameter choices that realize the diffusive-to-ballistic regime.
- [negative-result section] In the negative result for the Gaussian target, the entropy functional and the precise notion of “exponential convergence at any rate” should be stated explicitly before the obstruction argument (e.g., whether it is the relative entropy H(μ_t | π) or a weighted variant).
- A few typographical inconsistencies appear in the notation for the target density and the jump rates; these do not affect the logic but should be unified.
Simulated Author's Rebuttal
We thank the referee for their positive assessment of the manuscript, accurate summary of the main results on RHMC entropy speedup versus the BPS/ZZS obstruction, and recommendation of minor revision. No major comments are listed in the report.
Circularity Check
No significant circularity identified
full rationale
The paper's central claims establish a diffusive-to-ballistic speedup in relative entropy for RHMC under log-concave targets (extending prior L2/Harris hypocoercivity results) and demonstrate failure of exponential entropy convergence for BPS/ZZS even on the standard Gaussian. The stated assumptions (standard generators, jump mechanisms, and log-concavity) align with referenced external literature without reducing any prediction or rate to a fitted parameter, self-defined quantity, or self-citation chain. No load-bearing self-citations, ansatzes smuggled via prior work, or self-definitional steps are present; the derivation chain remains self-contained against external benchmarks.
Axiom & Free-Parameter Ledger
axioms (1)
- domain assumption Target distribution is log-concave
Reference graph
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