Energy efficiency maximisation based on RALA protocol for underlay D2D communication
Abstract
Energy efficiency (EE) maximisation is one of the most important necessities of the fifth‐generation (5G) wireless networks. In this study, both power allocation and channel assignment issues for the cellular network underlaid with device to device (D2D) communication are introduced. The main objective is to assign the users’ resources in order to maximise the total EE of the network. The distributions of both the D2D users (DUs) and the cellular users (CUs) are based on the stochastic geometry theory. Hence, the mathematical formula for the optimisation problem is demonstrated. Additionally, the resource allocation link admission (RALA) algorithm is proposed to achieve the maximum EE. Moreover, it assigns the optimal powers for each CU and DU in the system. Furthermore, the best channel assignment for each new D2D link request is determined. The optimisation problem in the RALA scheme is solved by utilising a proposed modified Cuckoo search algorithm. Furthermore, the complexity analysis for the proposed scheme is introduced. From simulation results, the proposed RALA scheme is efficient to assign the resource allocation for the users to achieve the near‐optimal EE.
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© 2021 The Institution of Engineering and Technology.
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John Wiley & Sons, Inc.
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Publication History
Published: 16 February 2021
Author Tags
Author Tags
- energy efficiency maximisation
- RALA protocol
- underlay D2D communication
- important necessities
- fifth‐generation wireless networks
- 5G
- power allocation
- channel assignment
- cellular network underlaid
- device communication
- cellular users
- stochastic geometry theory
- mathematical formula
- optimisation problem
- resource allocation link admission algorithm
- optimal powers
- D2D link request
- RALA scheme
- search algorithm
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