The Slepian zero set, and Brownian bridge embedded in Brownian motion by a spacetime shift

Pitman, Jim; Tang, Wenpin

doi:10.1214/ejp.v20-3911

Cited by 13 publications

(15 citation statements)

References 89 publications

(120 reference statements)

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“…The problem of embedding Brownian bridge b 0 into Brownian motion is treated in a subsequent work of Pitman and Tang [70]. Since the proof relies heavily on Palm theory of stationary random measures, we prefer not to include it in the current work.…”

Section: Introduction and Main Resultsmentioning

confidence: 99%

“…The process (S t := B t+1 − B t ; t ≥ 0) is a stationary Gaussian process, first studied by Slepian [79] and Shepp [77]. The following result, which can be found in Pitman and Tang [70,Lemma 2.3], is needed for the proof of Proposition 2.4.…”

Section: 3mentioning

confidence: 99%

“…Lemma 2.5. [76,70] For each fixed t ≥ 0, the distribution of (S u ; t ≤ u ≤ t + 1) is mutually absolutely continuous with respect to the distribution of…”

Section: 3mentioning

confidence: 99%

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Patterns in Random Walks and Brownian Motion

Pitman¹,

Tang²

2015

Lecture Notes in Mathematics

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We ask if it is possible to find some particular continuous paths of unit length in linear Brownian motion. Beginning with a discrete version of the problem, we derive the asymptotics of the expected waiting time for several interesting patterns. These suggest corresponding results on the existence/non-existence of continuous paths embedded in Brownian motion. With further effort we are able to prove some of these existence and non-existence results by various stochastic analysis arguments. A list of open problems is presented.

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Section: Introduction and Main Resultsmentioning

confidence: 99%

Section: 3mentioning

confidence: 99%

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Patterns in Random Walks and Brownian Motion

Pitman¹,

Tang²

2015

Lecture Notes in Mathematics

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“…In Table 3 we use Approximation 7 (our most accurate approximation) to approximate Λ(h) over increments 0.1 for h. Bold font indicates the decimal places which we claim accurate. Note that h = 0 has been treated as a special case, see for example [4] and [17]. For h = 0, instead of Approximation 7, we have used the approximation Λ (8) (h) = − log(F 5 (h)/F 4 (h)); we do not recommend using this approximation in general because of its high complexity.…”

Section: Approximations For λ(H)mentioning

confidence: 99%

Approximating Shepp’s constants for the Slepian process

Noonan

Zhigljavsky

2019

Statistics & Probability Letters

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Slepian process S(t) is a stationary Gaussian process with zero mean and covariance ES(t)S(t ) = max{0, 1 − |t − t |} . For any T ≥ 0 and real h, define F T (h) = Pr max t∈[0,T ] S(t) < h and the constants Λ(h) = − lim T →∞ 1 T log F T (h) and λ(h) = exp{−Λ(h)}; we will call them 'Shepp's constants'. The aim of the paper is construction of accurate approximations for F T (h) and hence for the Shepp's constants. We demonstrate that at least some of the approximations are extremely accurate.

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“…Pitman and Tang [112,Proposition 2.4] established the following invariance principle for the first hitting bridge {RW Fn+j − RW Fn ; 0 ≤ j ≤ n}.…”

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confidence: 99%

The spans in Brownian motion

Evans¹,

Pitman²,

Tang³

2017

Ann. Inst. H. Poincaré Probab. Statist.

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For $d \in \{1,2,3\}$, let $(B^d_t;~ t \geq 0)$ be a $d$-dimensional standard Brownian motion. We study the $d$-Brownian span set $Span(d):=\{t-s;~ B^d_s=B^d_t~\mbox{for some}~0 \leq s \leq t\}$. We prove that almost surely the random set $Span(d)$ is $\sigma$-compact and dense in $\mathbb{R}_{+}$. In addition, we show that $Span(1)=\mathbb{R}_{+}$ almost surely; the Lebesgue measure of $Span(2)$ is $0$ almost surely and its Hausdorff dimension is $1$ almost surely; and the Hausdorff dimension of $Span(3)$ is $\frac{1}{2}$ almost surely. We also list a number of conjectures and open problems.Comment: 33 pages, 4 figures. This paper is published by http://projecteuclid.org/euclid.aihp/150062403

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The Slepian zero set, and Brownian bridge embedded in Brownian motion by a spacetime shift

Cited by 13 publications

References 89 publications

Patterns in Random Walks and Brownian Motion

Patterns in Random Walks and Brownian Motion

Approximating Shepp’s constants for the Slepian process

The spans in Brownian motion

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