Abstract
With the augmentation of affordable multimedia wireless gadgets, the ubiquitous availability of the internet access, and the rapid pace of mobile traffic motivate research towards fifth generation (5G) communications to realize energy-efficient cloud radio access networks (C-RAN) with guaranteed quality of experience. Exploiting green energy harvesting for powering the C-RAN substantially alleviates the energy procurement from the utility grid, carbon footprint, and operational expenses. In this paper, we propose a new dynamic point selection coordinated multipoint (DPS CoMP) based load balancing paradigm emphasizing achievable throughput and energy efficiency (EE) by reducing utility grid consumption from a network level perspective. This paper investigates the radio efficiency, EE, and average on-grid energy saving addressing the key challenges of tempo-spatial dynamics of traffic intensity and renewable energy (RE) generation under a wide range of network setup. Endeavoring load balancing technique strives a balance in network utilities such as green energy utilization and user association based on BS coordination technique in a cluster. Provision of cell sleep approach is contemplated for further energy saving by turning off lightly loaded base stations (BSs) during low traffic arrivals. The proposed CoMP based load balancing algorithm proficiently manages resource block allocation to the new users and elevated the energy efficiency over the conventional location and traffic centric mechanisms. Extensive system-level simulations manifest that the suggested framework enables an adjustable trade-off between radio efficiency and EE, and saves 22% on-grid power consumption and increases EE index by 32%. Afterward, an exhaustive comparison of the proposed method with the existing schemes is pledged for further validation highlighting sustainable 5G wireless systems.
Highlights
Over the last few years, the emergence call for diversified wireless applications is growing astronomically due to the rapid boom of wireless subscribers, wide range of multimedia and data applications
The primary objective of this study is to develop a sustainable large-scale 5G cellular networks addressing energy efficiency and spectral efficiency aspects under existing resource availability utilizing the full advantage of renewable energy harvesting and coordinated multipoint (CoMP) technique
Radio efficiency load balancing, users are optimally connected to actively base stations (BSs) offering best received signal strength and traffic carrying capability regardless UE-BS distance
Summary
Over the last few years, the emergence call for diversified wireless applications is growing astronomically due to the rapid boom of wireless subscribers, wide range of multimedia and data applications. 8 billion mobile users are expected to increase by 2030 and over 10% global 5G mobile devices will be connected by 2023, which put an immense pressure to the existing networks and conventional utility grid as well [3] This volatile escalation of global traffic urges telecom operators to deploy massive number of cellular base stations to handle future demand by fulfilling. A suitable UE-BS connection policy balances the downlink traffic demand among collocated BSs that can downsize the on-grid energy consumption by enabling the capabilities of green-powered cellular BSs. This paper studies the throughput aware traffic load balancing scheme for the considered cellular layout to satisfy telecom providers’ requirements through balancing traffic arrivals under different conditions.
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