Efficient and accurate Lyapunov function-based truncation technique for multi-dimensional Markov chains with applications to discriminatory processor sharing and priority queues

IF 1 4区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Performance Evaluation Pub Date : 2023-08-10 DOI:10.1016/j.peva.2023.102356

Gagan Somashekar , Mohammad Delasay , Anshul Gandhi

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引用次数: 0

Abstract

Online service providers aim to satisfy the tail performance requirements of customers through Service-Level Objectives (SLOs). One approach to ensure tail performance requirements is to model the service as a Markov chain and obtain its steady-state probability distribution. However, obtaining the distribution can be challenging, if not impossible, for certain types of Markov chains, such as those with multi-dimensional or infinite state-space and state-dependent transitions. Examples include M/M/1 with Discriminatory Processor Sharing (DPS) and preemptive M/M/c with multiple priority classes and customer abandonment.

To address this fundamental problem, we propose a Lyapunov function-based state-space truncation technique that leverages moments or bounds on moments of the state variables. This technique allows us to obtain tight truncation bounds while ensuring arbitrary probability mass guarantees for the truncated chain. We highlight the efficacy of our technique for multi-dimensional DPS and M/M/c priority queue with abandonment, demonstrating a substantial reduction in state space (up to 74%) compared to existing approaches. Additionally, we present three practical use cases that highlight the applicability of our truncation technique by analyzing the performance of the DPS system.

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基于Lyapunov函数的多维马尔可夫链截断技术及其在判别处理器共享和优先级队列中的应用

在线服务提供商的目标是通过服务水平目标(service - level Objectives, slo)来满足客户的尾部性能需求。一种确保尾部性能要求的方法是将服务建模为马尔可夫链，并获得其稳态概率分布。然而，对于某些类型的马尔可夫链，例如具有多维或无限状态空间和状态依赖转换的马尔可夫链，获得分布可能是具有挑战性的，如果不是不可能的话。例子包括具有歧视性处理器共享(DPS)的M/M/1和具有多个优先级类和客户放弃的抢占式M/M/c。为了解决这个基本问题，我们提出了一种基于李雅普诺夫函数的状态空间截断技术，该技术利用状态变量的矩或矩界。这种技术允许我们在保证截断链的任意概率质量保证的同时获得严密的截断边界。我们强调了我们的技术在多维DPS和带放弃的M/M/c优先队列中的有效性，与现有方法相比，显示了状态空间的大幅减少(高达74%)。此外，我们提出了三个实际用例，通过分析DPS系统的性能来突出我们的截断技术的适用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Performance Evaluation 工程技术-计算机：理论方法

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

24 days

期刊介绍： Performance Evaluation functions as a leading journal in the area of modeling, measurement, and evaluation of performance aspects of computing and communication systems. As such, it aims to present a balanced and complete view of the entire Performance Evaluation profession. Hence, the journal is interested in papers that focus on one or more of the following dimensions: -Define new performance evaluation tools, including measurement and monitoring tools as well as modeling and analytic techniques -Provide new insights into the performance of computing and communication systems -Introduce new application areas where performance evaluation tools can play an important role and creative new uses for performance evaluation tools. More specifically, common application areas of interest include the performance of: -Resource allocation and control methods and algorithms (e.g. routing and flow control in networks, bandwidth allocation, processor scheduling, memory management) -System architecture, design and implementation -Cognitive radio -VANETs -Social networks and media -Energy efficient ICT -Energy harvesting -Data centers -Data centric networks -System reliability -System tuning and capacity planning -Wireless and sensor networks -Autonomic and self-organizing systems -Embedded systems -Network science