Extreme values for the waiting time in large fork-join queues

Dennis Schol; Maria Vlasiou; Bert Zwart

doi:10.1007/s11134-025-09937-2

Extreme values for the waiting time in large fork-join queues

Dennis Schol, Maria Vlasiou^*, Bert Zwart

^*Corresponding author for this work

Mathematics of Operations Research

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Abstract

We prove that the scaled maximum steady-state waiting time and the scaled maximum steady-state queue length among N GI/GI/1-queues in the N-server fork-join queue converge to a normally distributed random variable as N→∞. The maximum steady-state waiting time in this queueing system scales around 1γlogN, where γ is determined by the cumulant generating function Λ of the service times distribution and solves the Cramér–Lundberg equation with stochastic service times and deterministic interarrival times. This value 1γlogN is reached at a certain hitting time. The number of arrivals until that hitting time satisfies the central limit theorem, with standard deviation σAΛ′(γ)γ. By using the distributional form of Little’s law, we can extend this result to the maximum queue length. Finally, we extend these results to a fork-join queue with different classes of servers.

Original language	English
Article number	9
Journal	Queueing systems
Volume	109
Issue number	1
DOIs	https://doi.org/10.1007/s11134-025-09937-2
Publication status	Published - Mar 2025

Keywords

UT-Hybrid-D
Extreme value theory
Heterogeneous servers
Supply chains
Tail behaviour
Distributional Little’s Law

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10.1007/s11134-025-09937-2Licence: CC BY

s11134-025-09937-2Final published version, 420 KBLicence: CC BY

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title = "Extreme values for the waiting time in large fork-join queues",

abstract = "We prove that the scaled maximum steady-state waiting time and the scaled maximum steady-state queue length among N GI/GI/1-queues in the N-server fork-join queue converge to a normally distributed random variable as N→∞. The maximum steady-state waiting time in this queueing system scales around 1γlogN, where γ is determined by the cumulant generating function Λ of the service times distribution and solves the Cram{\'e}r–Lundberg equation with stochastic service times and deterministic interarrival times. This value 1γlogN is reached at a certain hitting time. The number of arrivals until that hitting time satisfies the central limit theorem, with standard deviation σAΛ′(γ)γ. By using the distributional form of Little{\textquoteright}s law, we can extend this result to the maximum queue length. Finally, we extend these results to a fork-join queue with different classes of servers.",

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N2 - We prove that the scaled maximum steady-state waiting time and the scaled maximum steady-state queue length among N GI/GI/1-queues in the N-server fork-join queue converge to a normally distributed random variable as N→∞. The maximum steady-state waiting time in this queueing system scales around 1γlogN, where γ is determined by the cumulant generating function Λ of the service times distribution and solves the Cramér–Lundberg equation with stochastic service times and deterministic interarrival times. This value 1γlogN is reached at a certain hitting time. The number of arrivals until that hitting time satisfies the central limit theorem, with standard deviation σAΛ′(γ)γ. By using the distributional form of Little’s law, we can extend this result to the maximum queue length. Finally, we extend these results to a fork-join queue with different classes of servers.

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Extreme values for the waiting time in large fork-join queues

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