2014
DOI: 10.1080/15326349.2014.900385
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First Passage Times to Congested States of Many-Server Systems in the Halfin–Whitt Regime

Abstract: We consider the heavy-traffic approximation to the GI/M/s queueing system in the Halfin-Whitt regime, where both the number of servers s and the arrival rate λ grow large (taking the service rate as unity), with λ = s − β √ s and β some constant. In this asymptotic regime, the queue length process can be approximated by a diffusion process that behaves like a Brownian motion with drift above zero and like an Ornstein-Uhlenbeck process below zero. We analyze the first passage times of this hybrid diffusion proc… Show more

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Cited by 6 publications
(7 citation statements)
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“…In the limit m → ∞, with the scaling in (2.104) and (3.25), the transform of the first passage distribution Q n (θ) for the M/M/m model has the limit P(x, θ) where We have previously obtained these results in [5], by directly solving the parabolic PDE satisfied by the diffusion approximation. Since 2D 1−θ (−β)+βD −θ (−β) = −2D ′ −θ (−β), Corollary 6 agrees with Theorems 1 and 2 in [5]. Now, we can also consider the Halfin-Whitt limit for the first passage distribution in the M/M/m + M model (with a fixed η > 0), and then Theorem 3 reduces to the following.…”
Section: First Passage Timesmentioning
confidence: 98%
See 1 more Smart Citation
“…In the limit m → ∞, with the scaling in (2.104) and (3.25), the transform of the first passage distribution Q n (θ) for the M/M/m model has the limit P(x, θ) where We have previously obtained these results in [5], by directly solving the parabolic PDE satisfied by the diffusion approximation. Since 2D 1−θ (−β)+βD −θ (−β) = −2D ′ −θ (−β), Corollary 6 agrees with Theorems 1 and 2 in [5]. Now, we can also consider the Halfin-Whitt limit for the first passage distribution in the M/M/m + M model (with a fixed η > 0), and then Theorem 3 reduces to the following.…”
Section: First Passage Timesmentioning
confidence: 98%
“…(2014), by directly solving the parabolic PDE satisfied by the diffusion approximation. Since , Corollary 6 agrees with Theorems 1 and 2 in Fralix et al.…”
Section: First Passage Timesmentioning
confidence: 99%
“…The limiting diffusion process (D(t)) t≥0 in Theorem 2.2 is a combination of a negative-drift Brownian motion in the upper half plane and an Ornstein-Uhlenbeck process in the lower half plane. We refer to this hybrid diffusion process as the Halfin-Whitt diffusion [143,42,27]. Studying this diffusion process provides valuable information for the systems performance.…”
Section: )mentioning
confidence: 99%
“…An alternative derivation of this spectral gap was presented in by [142,143], along with expressions for the Laplace transform over time, and the large-time asymptotics for the time-dependent density. First passage times to large levels corresponding to highly congested states were obtained in [105,42]. For obvious reasons, the QED regime is also referred to as the Halfin-Whitt regime, and both these names are used interchangeably in the literature.…”
Section: )mentioning
confidence: 99%
“…Now consider an asymptotic regime where the number of servers grows large, and additionally assume that N − λ(N) √ N → β as N → ∞ for some positive coefficient β > 0, i.e., the load per server approaches unity as 1 − β/ √ N. In terms of the aggregate traffic load and total service capacity, this scaling corresponds to the socalled Halfin-Whitt heavy-traffic regime which was introduced in the seminal paper [12] and has been extensively studied since. The set-up in [12], as well as the numerous model extensions in the literature (see [8,9,10,12,23,24,25], and the references therein), primarily considered a single centralized queue and server pool (M/M/N), rather than a scenario with parallel queues. Eschenfeldt and Gamarnik [7] initiated the study of the scaling behavior for parallel-server systems in the Halfin-Whitt heavy-traffic regime.…”
mentioning
confidence: 99%