Heterogeneous Computational Resource Allocation for NOMA: Toward Green Mobile Edge-Computing Systems

Heterogeneous Computational Resource Allocation for NOMA: Toward Green Mobile Edge-Computing Systems

Mobile Edge Computing (MEC) is a viable solution in response to the growing demand for broadband services in the new-generation heterogeneous systems. The dense deployment of small cell networks is a key feature of next-generation radio access networks aimed at providing the necessary capacity incre...

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Bibliographic Details
Published in:IEEE transactions on services computing Vol. 16; no. 2; pp. 1225 - 1238
Main Authors: Mohajer, Amin, Sam Daliri, Mahya, Mirzaei, A., Ziaeddini, A., Nabipour, M., Bavaghar, Maryam
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-03-2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Broadband
Carbon dioxide
Cellular communication
Computational modeling
Computational resource allocation
Edge computing
energy efficiency
Mobile computing
NOMA
NOMA HetNet
Optimization
Optimization models
Reliability
Resource allocation
Resource management
Resource scheduling
service fairness
Throughput
Traffic models
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Summary:Mobile Edge Computing (MEC) is a viable solution in response to the growing demand for broadband services in the new-generation heterogeneous systems. The dense deployment of small cell networks is a key feature of next-generation radio access networks aimed at providing the necessary capacity increase. Nonetheless, the problem of green networking and service computing will be of great importance in the downlink, because the uncontrolled installation of too many small cells may increase operational costs and emit more carbon dioxide. In addition, given the resource and computational limitation of the user layer, energy efficiency (EE) and fairness assurance are critical issues in MEC-based cellular systems. Considering the user fairness criteria, this paper proposes a dynamic optimization model which maximizes the total UL/DL EE along with satisfying the necessary QoS constraints. Based on the non-convex characteristics of the EE maximization problem, the mathematical model can be divided into two separate subproblems, i.e., computational carrier scheduling and resource allocation. So that, a subgradient method is applied for the computational resource allocation and also successive convex approximation (SCA) and dual decomposition methods are adopted to solve the max-min fairness problem. The simulation results exhibit considerable EE improvement for various traffic models in addition to guaranteeing the fairness requirements. It also proved that the proposed computational partitioning scheme managed to significantly improve the total throughput for mobile computing services.
ISSN:1939-1374
2372-0204
DOI:10.1109/TSC.2022.3186099