Abstract
In view of the growing contradiction between the intensive computation demands and the resource limitations of mobile users, mobile edge computing (MEC) and simultaneous wireless information and power transfer (SWIPT) have emerged as new paradigms towards 5G communication. However, coordinating the communication and computation between users and edge servers proves to be challenging for MEC. In this paper, we propose a novel multi-user full-duplex (FD) communication system that combines MEC and SWIPT technology in order to take the advantage of high-speed mobile computing and long-lasting self-sustainability. Through MEC technology, users are able to calculate local computation tasks using their batteries, and can offload partial computation tasks to the base station (BS) to reduce their energy shortage. Moreover, users can refill their batteries while receiving the computation result sent by the BS, thus benefiting from SWIPT technology. The FD mode can potentially increase the system performance by allowing the simultaneous transmitting and receiving of computation tasks. Our work aims to minimize the energy consumption of the system, while formulating resource allocation as a joint non-linear optimization problem. We decouple the original non-convex problem into two subproblems and solve them using a proposed algorithm that applies group iterative optimization. Numerical results prove that the proposed algorithm is superior to other two comparison schemes and can significantly reduce the system energy consumption and the latency.
Highlights
IntroductionIn 2016, Cisco reported that global mobile traffic will increase by more than seven times over the period of 2015-2020, while network connection speeds will almost quadruple by 2020
The era of the Internet of Things (IoT) has brought about a dramatic surge in data
We investigate a multi-input multi-output (MIMO) [27] FD-enabled wireless communication system integrated with mobile edge computing (MEC) and simultaneous wireless information and power transfer (SWIPT) technologies, which intend to meet the requirements of great computation capability, long battery lifetime, high spectral efficiency and low latency for the explosive expanding communications
Summary
In 2016, Cisco reported that global mobile traffic will increase by more than seven times over the period of 2015-2020, while network connection speeds will almost quadruple by 2020. Terminal connection types and service scenarios have exhibited an exponential growth. Ultra-low delay and ultra-high efficiency, reliability and density connections have become necessary requirements of future mobile communication systems [1]–[3], while accelerating the development and implementation of 5G systems [4]. (AR/VR) [5]–[7], automatic driving, industrial Internet, vehicle networking, smart cities, and smart agriculture [8], [9]. A novel network framework and corresponding resource management scheme are urgently required to take on the rapid development in technology that is currently observed [10]
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