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超越边界:一种用于边缘计算中能量和延迟优化的混合细胞自动机和粒子群优化模型

Beyond boundaries a hybrid cellular potts and particle swarm optimization model for energy and latency optimization in edge computing.

作者信息

Sahu Dinesh, Prakash Shiv, Sinha Priyanshu, Yang Tiansheng, Rathore Rajkumar Singh, Wang Lu

机构信息

SCSET, Bennett University, Plot Nos 8, 11, TechZone 2, Greater Noida, Uttar Pradesh, 201310, India.

Department of Electronics and Communication, University of Allahabad, Prayag Raj, Uttar Pradesh, India.

出版信息

Sci Rep. 2025 Feb 20;15(1):6266. doi: 10.1038/s41598-025-90348-x.

DOI:10.1038/s41598-025-90348-x
PMID:39979563
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11842745/
Abstract

The need to compute data in real-time and manage resources in environments with distributed computing has given edge computing significant importance. However, one of the most critical tasks regarding resources has been to schedule and optimize them in accordance with energy consumption and delay time. These challenges has been addressed in this paper with the introduction of a new integrated method that assumes the Cellular Potts Model and Particle Swarm Optimization. The Cellular Potts Model is used to capture local interaction and dependencies of resources, while PSO acts as a global optimizer for scheduling reducing latency and energy consumption. Based on these considerations, the primary research goal of this work is to mitigate the QoS requirements like energy consumption and end-to-end delay using CPM-spatial modeling complemented by PSO - the global optimization. Based on experimental analysis, the authors of the paper argue that the newly proposed Hybrid model consumes less energy and has less processing time than Round-Robin, Random Offloading, and Threshold-Based techniques. In addition, the approach achieves higher scalability and can perform a large of tasks and edge nodes with a high QoS while working in a resource-limited environment. This paper contributes to presenting the integration procedure of the CPM's local optimization with the PSO's global search, which offers high-performance and real-time solutions for resource scheduling in the edge computing environment. The results presented in the paper show that the proposed hybrid CPM-PSO model can offer greater potential as a tool for energy-constrained and time-sensitive applications within the future development of edge computing.

摘要

在分布式计算环境中实时计算数据和管理资源的需求,使得边缘计算变得极为重要。然而,资源管理方面最关键的任务之一,是根据能耗和延迟时间来调度和优化资源。本文通过引入一种新的集成方法来解决这些挑战,该方法采用了细胞 Potts 模型和粒子群优化算法。细胞 Potts 模型用于捕捉资源的局部交互和依赖性,而粒子群优化算法则作为全局优化器来进行调度,以减少延迟和能耗。基于这些考虑,这项工作的主要研究目标是使用由粒子群优化算法(全局优化)补充的细胞 Potts 模型空间建模,来减轻诸如能耗和端到端延迟等服务质量要求。基于实验分析,本文作者认为新提出的混合模型比轮询、随机卸载和基于阈值的技术消耗更少的能量且处理时间更短。此外,该方法具有更高的可扩展性,并且在资源受限的环境中工作时,能够以高服务质量执行大量任务和边缘节点。本文有助于展示细胞 Potts 模型的局部优化与粒子群优化算法的全局搜索的集成过程,为边缘计算环境中的资源调度提供了高性能的实时解决方案。本文给出的结果表明,所提出的混合细胞 Potts 模型 - 粒子群优化算法模型,在边缘计算未来发展中,作为能源受限和时间敏感型应用的工具,具有更大的潜力。

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1
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2
Optimal design of hybrid green energy powered reduced switch converter based shunt active power filter using horse herd algorithm.基于马群算法的混合绿色能源供电的降压式开关变换器并联型有源电力滤波器的优化设计
Sci Rep. 2024 Sep 3;14(1):20447. doi: 10.1038/s41598-024-71100-3.
3
Hybrid genetic algorithm-simulated annealing based electric vehicle charging station placement for optimizing distribution network resilience.
使用基于禁忌搜索的优化随机森林增强无线传感器网络中的入侵检测
Sci Rep. 2025 May 28;15(1):18634. doi: 10.1038/s41598-025-03498-3.
4
Edge assisted energy optimization for mobile AR applications for enhanced battery life and performance.用于移动增强现实应用的边缘辅助能量优化,以延长电池寿命并提升性能。
Sci Rep. 2025 Mar 23;15(1):10034. doi: 10.1038/s41598-025-93731-w.
5
A high performance hybrid LSTM CNN secure architecture for IoT environments using deep learning.一种用于物联网环境的基于深度学习的高性能混合长短期记忆网络-卷积神经网络安全架构。
Sci Rep. 2025 Mar 20;15(1):9684. doi: 10.1038/s41598-025-94500-5.
基于混合遗传算法-模拟退火的电动汽车充电站布局以优化配电网弹性
Sci Rep. 2024 Apr 1;14(1):7637. doi: 10.1038/s41598-024-58024-8.
4
Development of renewable energy fed three-level hybrid active filter for EV charging station load using Jaya grey wolf optimization.基于Jaya灰狼优化算法的电动汽车充电站负载用可再生能源馈电三电平混合有源滤波器的开发
Sci Rep. 2024 Feb 23;14(1):4429. doi: 10.1038/s41598-024-54550-7.
5
From energy to cellular forces in the Cellular Potts Model: An algorithmic approach.从细胞势模型中的能量到细胞力:一种算法方法。
PLoS Comput Biol. 2019 Dec 11;15(12):e1007459. doi: 10.1371/journal.pcbi.1007459. eCollection 2019 Dec.
6
Load balancing prediction method of cloud storage based on analytic hierarchy process and hybrid hierarchical genetic algorithm.基于层次分析法和混合层次遗传算法的云存储负载均衡预测方法
Springerplus. 2016 Nov 17;5(1):1989. doi: 10.1186/s40064-016-3619-x. eCollection 2016.
7
A parallel implementation of the Cellular Potts Model for simulation of cell-based morphogenesis.用于基于细胞的形态发生模拟的细胞Potts模型的并行实现。
Comput Phys Commun. 2007 Jun;176(11-12):670-681. doi: 10.1016/j.cpc.2007.03.007.
8
Simulation of biological cell sorting using a two-dimensional extended Potts model.使用二维扩展Potts模型对生物细胞分选进行模拟。
Phys Rev Lett. 1992 Sep 28;69(13):2013-2016. doi: 10.1103/PhysRevLett.69.2013.
9
Simulation of the differential adhesion driven rearrangement of biological cells.生物细胞差异黏附驱动重排的模拟。
Phys Rev E Stat Phys Plasmas Fluids Relat Interdiscip Topics. 1993 Mar;47(3):2128-2154. doi: 10.1103/physreve.47.2128.