Dynamic Scheduling for Stochastic Edge-Cloud Computing Environments Using A3C Learning and Residual Recurrent Neural Networks
Autor: | Kotagiri Ramamohanarao, Shreshth Tuli, Rajkumar Buyya, Shashikant Ilager |
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Rok vydání: | 2022 |
Předmět: |
FOS: Computer and information sciences
Computer Science - Machine Learning Computer Networks and Communications Computer science Heuristic business.industry Distributed computing 020206 networking & telecommunications Workload Cloud computing 02 engineering and technology Dynamic priority scheduling Energy consumption Machine Learning (cs.LG) Scheduling (computing) Recurrent neural network Computer Science - Distributed Parallel and Cluster Computing 0202 electrical engineering electronic engineering information engineering Reinforcement learning Distributed Parallel and Cluster Computing (cs.DC) Electrical and Electronic Engineering Hierarchical network model business Software Edge computing |
Zdroj: | IEEE Transactions on Mobile Computing. 21:940-954 |
ISSN: | 2161-9875 1536-1233 |
Popis: | The ubiquitous adoption of Internet-of-Things (IoT) based applications has resulted in the emergence of the Fog computing paradigm, which allows seamlessly harnessing both mobile-edge and cloud resources. Efficient scheduling of application tasks in such environments is challenging due to constrained resource capabilities, mobility factors in IoT, resource heterogeneity, network hierarchy, and stochastic behaviors. xisting heuristics and Reinforcement Learning based approaches lack generalizability and quick adaptability, thus failing to tackle this problem optimally. They are also unable to utilize the temporal workload patterns and are suitable only for centralized setups. However, Asynchronous-Advantage-Actor-Critic (A3C) learning is known to quickly adapt to dynamic scenarios with less data and Residual Recurrent Neural Network (R2N2) to quickly update model parameters. Thus, we propose an A3C based real-time scheduler for stochastic Edge-Cloud environments allowing decentralized learning, concurrently across multiple agents. We use the R2N2 architecture to capture a large number of host and task parameters together with temporal patterns to provide efficient scheduling decisions. The proposed model is adaptive and able to tune different hyper-parameters based on the application requirements. We explicate our choice of hyper-parameters through sensitivity analysis. The experiments conducted on real-world data set show a significant improvement in terms of energy consumption, response time, Service-Level-Agreement and running cost by 14.4%, 7.74%, 31.9%, and 4.64%, respectively when compared to the state-of-the-art algorithms. Comment: Accepted in IEEE Transaction on Mobile Computing |
Databáze: | OpenAIRE |
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