Hybrid metaheuristics for selective inference task offloading under time and energy constraints for real-time IoT sensing systems

Abdelkarim Ben Sada, Amar Khelloufi, Abdenacer Naouri, Huansheng Ning, Sahraoui Dhelim
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Abstract

The recent widespread of AI-powered real-time applications necessitates the use of edge computing for inference task offloading. Power constrained edge devices are required to balance between processing inference tasks locally or offload to edge servers. This decision is determined according to the time constraint demanded by the real-time nature of applications, and the energy constraint dictated by the device’s power budget. This problem is further exacerbated in the case of systems leveraging multiple local inference models varying in size and accuracy. In this work, we tackle the problem of assigning inference models to inference tasks either using local inference models or by offloading to edge servers under time and energy constraints while maximizing the overall accuracy of the system. This problem is shown to be strongly NP-hard and therefore, we propose a hybrid genetic algorithm (HGSTO) to solve this problem. We leverage the speed of simulated annealing (SA) with the accuracy of genetic algorithms (GA) to develop a hybrid, fast and accurate algorithm compared with classic GA, SA and Particle Swarm Optimization (PSO). Experiment results show that HGSTO achieved on-par or higher accuracy than GA while resulting in significantly lower scheduling times compared to other schemes.

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实时物联网传感系统在时间和能量限制下选择性推理任务卸载的混合元启发式算法
最近,人工智能驱动的实时应用越来越广泛,因此有必要使用边缘计算来卸载推理任务。功率受限的边缘设备需要在本地处理推理任务或将任务卸载到边缘服务器之间取得平衡。这一决定是根据应用的实时性所要求的时间限制和设备的功率预算所决定的能耗限制来做出的。如果系统利用多个规模和精度各不相同的本地推理模型,这个问题就会进一步恶化。在这项工作中,我们要解决的问题是,在时间和能量限制下,利用本地推理模型或通过卸载到边缘服务器来为推理任务分配推理模型,同时最大限度地提高系统的整体准确性。这个问题被证明是强 NP 难,因此我们提出了一种混合遗传算法 (HGSTO) 来解决这个问题。我们利用模拟退火(SA)的速度和遗传算法(GA)的准确性,开发出一种混合、快速、准确的算法,与传统的 GA、SA 和粒子群优化(PSO)相比,具有更高的准确性。实验结果表明,与其他方案相比,HGSTO 实现了与 GA 相当或更高的精确度,同时大大缩短了调度时间。
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