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arxiv: 1907.02676 · v2 · pith:NRD2QVFGnew · submitted 2019-07-05 · 📊 stat.CO · stat.OT

On the Convergence Rate of the Quasi- to Stationary Distribution for the Shiryaev-Roberts Diffusion

Kexuan Li , Aleksey S. Polunchenko This is my paper

Pith reviewed 2026-05-25 02:13 UTC · model grok-4.3

classification 📊 stat.CO stat.OT
keywords quasi-stationary distributionShiryaev-Roberts diffusionconvergence ratemodified Bessel functionabsorbing boundarystationary distribution
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The pith

The quasi-stationary cdf of the Shiryaev-Roberts diffusion converges to the stationary cdf at rate O(log(A)/A) uniformly as the absorbing boundary A tends to infinity.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper establishes that the quasi-stationary cumulative distribution function Q_A(x) of the Shiryaev-Roberts diffusion on [0,A] approaches its stationary counterpart H(x) at a rate no worse than O(log(A)/A) as A grows large, and that this holds uniformly for all x at least zero. The bound is obtained explicitly by sandwiching Q_A(x) between new lower and upper estimates that exploit the exact closed-form expression for Q_A(x) and the monotonicity properties of the modified Bessel K function appearing in that expression. A sympathetic reader would care because the result quantifies how the influence of a distant absorbing barrier fades in the long-run distribution of the process.

Core claim

It is shown that the rate of convergence of the diffusion's quasi-stationary cumulative distribution function Q_A(x) to its stationary cdf H(x), as A→+∞, is no worse than O(log(A)/A), uniformly in x≥0. The result is established explicitly by constructing new tight lower- and upper-bounds for Q_A(x) using certain latest monotonicity properties of the modified Bessel K function involved in the exact closed-form formula for Q_A(x) recently obtained by Polunchenko (2017).

What carries the argument

The exact closed-form formula for Q_A(x) involving the modified Bessel function of the second kind, whose monotonicity properties are used to derive explicit sandwiching bounds on the difference from the stationary cdf H(x).

If this is right

  • The stated rate bound holds uniformly over the entire state space x ≥ 0.
  • The explicit bounds on Q_A(x) are obtained directly from the closed-form expression without additional approximation steps.
  • The convergence rate tends to zero as A increases, confirming that the effect of the absorbing boundary vanishes in the limit.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

  • The same monotonicity technique on the Bessel K function could be applied to quasi-stationary distributions of related one-dimensional diffusions that admit similar closed forms.
  • The O(log(A)/A) rate supplies a concrete error term that can be plugged into performance analyses of change detection procedures that rely on the Shiryaev-Roberts statistic with a large threshold.

Load-bearing premise

The exact closed-form formula for Q_A(x) from Polunchenko (2017) together with the monotonicity properties of the modified Bessel K function are sufficient to construct the stated tight bounds.

What would settle it

A direct numerical evaluation of |Q_A(x) - H(x)| for successively larger A that exceeds C log(A)/A for every fixed C and some x would falsify the claimed uniform rate.

read the original abstract

For the classical Shiryaev--Roberts martingale diffusion considered on the interval $[0,A]$, where $A>0$ is a given absorbing boundary, it is shown that the rate of convergence of the diffusion's quasi-stationary cumulative distribution function (cdf), $Q_{A}(x)$, to its stationary cdf, $H(x)$, as $A\to+\infty$, is no worse than $O(\log(A)/A)$, uniformly in $x\ge0$. The result is established explicitly, by constructing new tight lower- and upper-bounds for $Q_{A}(x)$ using certain latest monotonicity properties of the modified Bessel $K$ function involved in the exact closed-form formula for $Q_{A}(x)$ recently obtained by Polunchenko (2017).

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Referee Report

0 major / 3 minor

Summary. The paper claims that for the Shiryaev-Roberts martingale diffusion on [0,A] with absorbing boundary at A>0, the quasi-stationary cdf Q_A(x) converges to the stationary cdf H(x) as A→+∞ at a rate no worse than O(log(A)/A), uniformly in x≥0. The result is obtained explicitly by constructing tight lower and upper bounds on |Q_A(x)−H(x)| from the closed-form expression for Q_A(x) in Polunchenko (2017) together with monotonicity properties of the modified Bessel K function.

Significance. If the bounds are valid, the explicit rate supplies a concrete, verifiable quantification of the approximation quality between quasi-stationary and stationary regimes for large thresholds. This is useful in sequential analysis. The direct analytic derivation from the 2017 closed form, rather than an appeal to general convergence theorems, is a methodological strength that makes the result self-contained and potentially reproducible.

minor comments (3)
  1. Abstract: the phrase 'certain latest monotonicity properties' of the modified Bessel K function should be accompanied by an explicit citation to the source of those properties.
  2. The manuscript should verify in the main derivation that the implicit constants in the O(log(A)/A) bound are independent of x, so that uniformity is immediate from the stated inequalities.
  3. All displayed equations involving the difference Q_A(x)−H(x) should be numbered consecutively and cross-referenced in the text when the bounds are applied.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the careful reading and positive assessment of the manuscript, including the accurate summary of the main result and the recommendation for minor revision. No specific major comments were raised.

Circularity Check

1 steps flagged

Minor self-citation to co-author's 2017 closed-form; rate bound derived independently via new inequalities

specific steps
  1. self citation load bearing [Abstract and Section 1 (introduction of Q_A(x))]
    "using certain latest monotonicity properties of the modified Bessel K function involved in the exact closed-form formula for Q_A(x) recently obtained by Polunchenko (2017)"

    The citation supplies the closed-form expression that is then manipulated to produce the convergence-rate bound. While the manipulation is new, the load-bearing input is a result by a co-author; however the bound itself is not tautological with the 2017 formula and therefore does not meet the stricter load-bearing circularity threshold.

full rationale

The paper cites Polunchenko (2017) solely for the explicit formula of Q_A(x) involving the modified Bessel K function. From this input the authors construct fresh lower/upper bounds on |Q_A(x) - H(x)| by invoking monotonicity properties of K and direct integral estimates, yielding the O(log(A)/A) rate uniformly in x. This is a standard use of a prior mathematical result as a starting point rather than a reduction of the target claim to the citation itself. No self-definitional loop, fitted-input prediction, uniqueness theorem, or ansatz smuggling is present. The central derivation remains analytically independent of the 2017 paper beyond the shared formula.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The result rests on the 2017 closed-form expression for Q_A(x) and standard analytic properties of the modified Bessel function of the second kind; no new free parameters or postulated entities are introduced.

axioms (1)
  • standard math Monotonicity properties of the modified Bessel K function
    Used to obtain tight lower and upper bounds on Q_A(x)

pith-pipeline@v0.9.0 · 5670 in / 1037 out tokens · 25848 ms · 2026-05-25T02:13:30.289140+00:00 · methodology

discussion (0)

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