Research Article
Multiple Time Blocks Energy Harvesting Relay Optimizing with Time-Switching Structure and Decoding Cost
@INPROCEEDINGS{10.1007/978-3-030-48513-9_49, author={Chenxu Wang and Yanxin Yao and Zhengwei Ni and Rajshekhar Bhat and Mehul Motani}, title={Multiple Time Blocks Energy Harvesting Relay Optimizing with Time-Switching Structure and Decoding Cost}, proceedings={Cloud Computing, Smart Grid and Innovative Frontiers in Telecommunications. 9th EAI International Conference, CloudComp 2019, and 4th EAI International Conference, SmartGIFT 2019, Beijing, China, December 4-5, 2019, and December 21-22, 2019}, proceedings_a={CLOUDCOMP}, year={2020}, month={6}, keywords={Energy harvesting Time-switching Harvest-transmit-then-receive Relay}, doi={10.1007/978-3-030-48513-9_49} }
- Chenxu Wang
Yanxin Yao
Zhengwei Ni
Rajshekhar Bhat
Mehul Motani
Year: 2020
Multiple Time Blocks Energy Harvesting Relay Optimizing with Time-Switching Structure and Decoding Cost
CLOUDCOMP
Springer
DOI: 10.1007/978-3-030-48513-9_49
Abstract
Energy harvesting (EH) is of prime importance for enabling the Internet of Things (IoT) networks. Although, energy harvesting relays have been considered in the literature, most of the studies do not account for the processing costs, such as the decoding cost in a decode-and-forward (DF) relay. However, it is known that the decoding cost amounts to a significant fraction of the circuit power required for receiving a codeword. Hence, in this work, we are motivated to consider an EH-DF relay with the decoding cost and maximize the average number of bits relayed by it with a time-switching architecture. To achieve this, we first propose a frame structure consisting of three phases: (i) an energy harvesting phase, (ii) a reception phase and, (iii) a transmission phase. We obtain optimal length of each of the above phases and communication rates that maximize the average number of bits relayed. We consider the radio frequency (RF) energy to be harvested by the relay is from the dedicated transmitter and the multiple block case when energy is allowed from flow among the blocks, different from the single block case when energy is not allowed to flow among the blocks. By exploiting the convexity of the optimization problem, we derive analytical optimum solutions under the EH scenario. One of the optimal receiving rate for the relay is the same as in single block case. We also provide numerical simulations for verifying our theoretical analysis.