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Main Author: El-Taha, Muhammad
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.01696
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author El-Taha, Muhammad
author_facet El-Taha, Muhammad
contents In this article we classify discrete-time queues based on scheduling rules and observation epochs combinations. This classification leads to {\em coherent}, {\em sub-coherent}, and {\em super-coherent} systems when {\em observed} waiting times are, respectively equal to, less than, or larger than {actual} waiting times. We then explore the consequences of this classification. Specifically, we discuss invariant properties of {\em coherent} systems including queue-lengths, waiting times, servers' busy times, busy periods, Pollaczek-Khinchine formula, and other common characteristics. An important consequence is that a performance characteristic of a system with specific scheduling rule and observation epoch combination extends to the entire class. An unresolved issue in the literature is the assertion that Little's law does not apply for discrete-time queues that incorporate certain scheduling rules. Using this classification, we reconcile the generality of Little's law and its applicability to all discrete-time queues regardless of scheduling rules.
format Preprint
id arxiv_https___arxiv_org_abs_2509_01696
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Classification of Discrete-Time Queues
El-Taha, Muhammad
Probability
60k25
In this article we classify discrete-time queues based on scheduling rules and observation epochs combinations. This classification leads to {\em coherent}, {\em sub-coherent}, and {\em super-coherent} systems when {\em observed} waiting times are, respectively equal to, less than, or larger than {actual} waiting times. We then explore the consequences of this classification. Specifically, we discuss invariant properties of {\em coherent} systems including queue-lengths, waiting times, servers' busy times, busy periods, Pollaczek-Khinchine formula, and other common characteristics. An important consequence is that a performance characteristic of a system with specific scheduling rule and observation epoch combination extends to the entire class. An unresolved issue in the literature is the assertion that Little's law does not apply for discrete-time queues that incorporate certain scheduling rules. Using this classification, we reconcile the generality of Little's law and its applicability to all discrete-time queues regardless of scheduling rules.
title Classification of Discrete-Time Queues
topic Probability
60k25
url https://arxiv.org/abs/2509.01696