Egret: Reinforcement Mechanism for Sequential Computation Offloading in Edge Computing

被引:1
作者
Peng, Haosong [1 ]
Zhan, Yufeng [1 ]
Zhai, Di-Hua [1 ]
Zhang, Xiaopu [2 ]
Xia, Yuanqing [1 ]
机构
[1] Beijing Inst Technol, Sch Automat, Beijing 100086, Peoples R China
[2] Beijing Teleinfo Technol Co Ltd, IF Labs, Beijing 100095, Peoples R China
来源
IEEE TRANSACTIONS ON SERVICES COMPUTING | 2024年 / 17卷 / 06期
基金
中国国家自然科学基金;
关键词
Pricing; Computational modeling; Heuristic algorithms; Costs; Servers; Games; Privacy; Multi-access edge computing; Deep reinforcement learning; Bandwidth; Computation offloading; deep reinforcement learning; edge computing; sequential pricing; GAME;
D O I
10.1109/TSC.2024.3478826
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
As an emerging computing paradigm, edge computing offers computational resources closer to the data sources, helping to improve the service quality of many real-time applications. A crucial problem is designing a rational pricing mechanism to maximize the revenue of the edge computing service provider (ECSP). However, prior works have considerable limitations: clients are static and are required to disclose their preferences, which is impractical. To address this issue, we propose a novel sequential computation offloading mechanism, where the ECSP posts prices of computational resources with different configurations to clients in turn. Clients independently choose which computational resources to rent and how to offload based on their prices. Then Egret, a deep reinforcement learning-based approach that achieves maximum revenue, is proposed. Egret determines the optimal price and visiting orders online without infringing on clients' privacy. Experimental results show that the revenue of ECSP in Egret is only 1.29% lower than Oracle and 23.43% better than the state-of-the-art when the client arrives dynamically.
引用
收藏
页码:3541 / 3554
页数:14
相关论文
共 55 条
  • [1] Zhang X., Et al., EMP: Edge-assisted multi-vehicle perception, Proc. 27th Annu. Int. Conf. Mobile Comput. Netw., pp. 545-558, (2021)
  • [2] Li J., Et al., Learning for vehicle-to-vehicle cooperative perception under lossy communication, IEEE Trans. Intell. Veh., 8, 4, pp. 2650-2660, (2023)
  • [3] Yi J., Choi S., Lee Y., EagleEye: Wearable camera-based person identification in crowded urban spaces, Proc. 26th Annu. Int. Conf. Mobile Comput. Netw., pp. 1-14, (2020)
  • [4] Wang H., Et al., VaBUS: Edge-cloud real-time video analytics via background understanding and subtraction, IEEE J. Sel. Areas Commun., 41, 1, pp. 90-106, (2023)
  • [5] Liu L., Li H., Gruteser M., Edge assisted real-time object detection for mobile augmented reality, Proc. Annu. Int. Conf. Mobile Comput. Netw., pp. 1-16, (2019)
  • [6] Hieu N.Q., Nguyen D.N., Hoang D.T., Dutkiewicz E., When virtual reality meets rate splitting multiple access: A joint communication and computation approach, IEEE J. Sel. Areas Commun., 41, 5, pp. 1536-1548, (2023)
  • [7] Yao S., Et al., Deep compressive offloading: Speeding up neural network inference by trading edge computation for network latency, Proc. 18th Conf. Embedded Netw. Sensor Syst., pp. 476-488, (2020)
  • [8] Wu J., Wang L., Pei Q., Cui X., Liu F., Yang T., HiTDL: Highthroughput deep learning inference at the hybrid mobile edge, IEEE Trans. Parallel Distrib. Syst., 33, 12, pp. 4499-4514, (2022)
  • [9] Khani M., Hamadanian P., Nasr-Esfahany A., Alizadeh M., Real-time video inference on edge devices via adaptive model streaming, Proc. IEEE/CVF Int. Conf. Comput. Vis., pp. 4572-4582, (2021)
  • [10] Bhardwaj R., Et al., Ekya: Continuous learning of video analytics models on edge compute servers, Proc. 19th USENIX Symp. Netw. Syst. Des. Implementation, pp. 119-135, (2022)
123456