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Joint Computation and Communication Cooperation for Energy-Efficient Mobile Edge Computing (1805.05906v2)

Published 15 May 2018 in cs.IT and math.IT

Abstract: This paper proposes a novel user cooperation approach in both computation and communication for mobile edge computing (MEC) systems to improve the energy efficiency for latency-constrained computation. We consider a basic three-node MEC system consisting of a user node, a helper node, and an access point (AP) node attached with an MEC server, in which the user has latency-constrained and computation-intensive tasks to be executed. We consider two different computation offloading models, namely the partial and binary offloading, respectively. Under this setup, we focus on a particular finite time block and develop an efficient four-slot transmission protocol to enable the joint computation and communication cooperation. Besides the local task computing over the whole block, the user can offload some computation tasks to the helper in the first slot, and the helper cooperatively computes these tasks in the remaining time; while in the second and third slots, the helper works as a cooperative relay to help the user offload some other tasks to the AP for remote execution in the fourth slot. For both cases with partial and binary offloading, we jointly optimize the computation and communication resources allocation at both the user and the helper (i.e., the time and transmit power allocations for offloading, and the CPU frequencies for computing), so as to minimize their total energy consumption while satisfying the user's computation latency constraint. Although the two problems are non-convex in general, we propose efficient algorithms to solve them optimally. Numerical results show that the proposed joint computation and communication cooperation approach significantly improves the computation capacity and energy efficiency at the user and helper nodes, as compared to other benchmark schemes without such a joint design.

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Authors (5)
  1. Xiaowen Cao (17 papers)
  2. Feng Wang (408 papers)
  3. Jie Xu (467 papers)
  4. Rui Zhang (1138 papers)
  5. Shuguang Cui (275 papers)
Citations (252)

Summary

  • The paper introduces a user cooperation framework combining partial and binary offloading for energy-efficient task processing in MEC systems.
  • It develops novel convex optimization algorithms for resource allocation that minimize computational energy while meeting strict latency requirements.
  • Numerical results highlight significant energy savings over conventional designs, offering practical insights for scalable 5G and MEC applications.

An Analysis of Joint Computation and Communication Cooperation for Mobile Edge Computing

The paper "Joint Computation and Communication Cooperation for Energy-Efficient Mobile Edge Computing" presents an innovative approach to enhance energy efficiency in Mobile Edge Computing (MEC) systems facing latency constraints. This research is situated in the context of rapidly advancing 5G technologies which necessitate new methodologies to meet the low-latency and high-computation demands of emerging applications like augmented reality (AR), autonomous driving, and the Internet of Things (IoT).

Overview of the Proposed Approach

The authors introduce a user cooperation framework in both computation and communication domains within a three-node MEC system. This system comprises a user node, a helper node, and an access point (AP) node with an attached MEC server. Their methodology incorporates two prominent computation offloading models: partial offloading and binary offloading.

  • Partial Offloading: Tasks are divided among the user, helper, and AP.
  • Binary Offloading: Tasks are processed as a complete unit at a single node, such as the user, helper, or AP.

The authors develop a four-slot transmission protocol directed at optimizing computational energy. In this setup, various tasks are processed either locally, offloaded to a helper, or offloaded to the AP. The authors propose detailed algorithms for optimizing resource allocation including time, transmit power, and CPU frequency settings to minimize energy while satisfying latency requirements.

Key Contributions and Results

  1. Energy-efficient Algorithm Development: For both partial and binary offloading scenarios, the authors derive structured and tractable optimization schemes. The proposed algorithms, founded on convex optimization principles and Lagrange duality, effectively solve the inherently non-convex problems posed.
  2. Theoretical and Practical Implications: The research elucidates how user cooperation can substantially enhance energy efficiency and computational capacity. This framework allows MEC systems to provide cloud-like computational power without the latency overhead associated with distant cloud servers.
  3. Numerical Validation: The simulation results demonstrate significant energy-saving opportunities through the proposed joint cooperation framework when compared to conventional designs without cooperation.

Implications and Future Directions

This paper offers substantial implications for both the theoretical understanding and practical deployment of MEC systems. By leveraging both computation and communication cooperation, the authors provide a pathway for MEC systems to tackle the burgeoning demands posed by 5G network applications effectively.

Future developments might explore extending this cooperation model to multi-user systems. While the paper focuses on a three-node setting, scaling to environments with numerous users and helpers could present unique challenges and opportunities. Moreover, the exploration of incentive mechanisms in scenarios where nodes have varying incentives to participate would provide a valuable complement to the proposed cooperative framework.

Conclusion

The research by Cao et al. makes a significant contribution to the field of mobile edge computing by advancing a joint computation and communication cooperation model. It sets a course toward MEC systems that better meet the energy efficiency and latency requirements of future applications. Follow-up work that investigates multi-node scalability and addresses practical deployment scenarios in real-world networks could yield further insights, also broadening the applicability of these findings in the fast-evolving terrain of 5G and beyond.