源节点电池容量受限的菱形信道最优传输策略

doi:10.11959/j.issn.1000-436x.2021069

Abstract

Abstract:

In order to solve the problem that the energy harvesting uncertainty of node in wireless energy harvesting network makes it difficult for the system to design a reasonable transmission strategy, a diamond channel with limited battery capacity of the source node were constructed.The goal was to maximize the end-to-end throughput of the system.Under the conditions of meeting the constraints of energy and data causality between transmission nodes and no battery energy overflow, a model to maximize the end-to-end throughput of the system was built, and an optimal offline transmission power and rate allocation strategy was proposed.Firstly, based on theoretical analysis and formula derivation, the strategy transformed the optimal transmission problem into the optimal transmission problem on the side of the broadcast channel, and used the water-filling algorithm to solve the optimal total power from the source node to the relay node.Then, the throughput of the source node to each relay node was analyzed based on the cutoff power level in the broadcast channel throughput maximization problem.Finally, according to the data arrival of the relay node, the iterative water-filling method was used to solve the optimal transmission power from the relay node to the destination node, and the optimal rate was solved by extending the optimal rate of the multiple access channel.Simulation results demonstrate the feasibility and correctness of the proposed optimization policies.

Key words: energy harvesting, diamond channel, limited battery capacity, optimal power allocation, maximum throughput

CLC Number:

TP393

Taoshen LI, Li SUN, Zhe WANG. Optimal transmission strategy of diamond channel with limited battery capacity of source node[J]. Journal on Communications, 2021, 42(6): 158-170.

Figures/Tables 9

References 26

[1]	PRASAD R V , DEVASENAPATHY S , RAO V S ,et al. Reincarnation in the ambiance:devices and networks with energy harvesting[J]. IEEE Communications Surveys ＆ Tutorials, 2014,16(1): 195-213.
[2]	SUDEVALAYAM S , KULKARNI P . Energy harvesting sensor nodes:survey and implications[J]. IEEE Communications Surveys ＆ Tutorials, 2011,13(3): 443-461.
[3]	SIRDESHPANDE N , UDUPI V . Data delivery scheme using RF-energy harvesting for wireless sensor networks[C]// International Conference on Circuits,Communication,Control and Computing. Piscataway:IEEE Press, 2014: 285-290.
[4]	王哲, 李陶深, 叶进 ,等. 基于不确定理论的能量收集可靠性建模及规划[J]. 通信学报, 2018,39(5): 166-176.
	WANG Z , LI T S , YE J ,et al. Reliability modeling and planning of energy harvesting based on uncertainty theory[J]. Journal on Communications, 2018,39(5): 166-176.
[5]	王哲, 李陶深, 叶进 ,等. 能量收集网络技术研究与发展[J]. 广西科学, 2019,26(3): 253-266,355.
	WANG Z , LI T S , YE J ,et al. Energy harvesting networks:a review of recent advances[J]. Guangxi Sciences, 2019,26(3): 253-266,355.
[6]	TUTUNCUOGLU K , YENER A . Optimum transmission policies for battery limited energy harvesting nodes[J]. IEEE Transactions on Wireless Communications, 2012,11(3): 1180-1189.
[7]	OZEL O , TUTUNCUOGLU K , YANG J ,et al. Transmission with energy harvesting nodes in fading wireless channels:optimal policies[J]. IEEE Journal on Selected Areas in Communications, 2011,29(8): 1732-1743.
[8]	OZEL O , YANG J , ULUKUS S . Broadcasting with a battery limited energy harvesting rechargeable transmitter[C]// 2011 International Symposium of Modeling and Optimization of Mobile,Ad Hoc,and Wireless Networks. Piscataway:IEEE Press, 2011: 205-212.
[9]	OZEL O , YANG J , ULUKUS S . Optimal broadcast scheduling for an energy harvesting rechargeable transmitter with a finite capacity battery[J]. IEEE Transactions on Wireless Communications, 2012,11(6): 2193-2203.
[10]	ORHAN O , ERKIP E . Optimal transmission policies for energy harvesting two-hop networks[C]// 2012 46th Annual Conference on Information Sciences and Systems. Piscataway:IEEE Press, 2012: 1-6.
[11]	QIAN L P , FENG G N , LEUNG V C M . Optimal transmission policies for relay communication networks with ambient energy harvesting relays[J]. IEEE Journal on Selected Areas in Communications, 2016,34(12): 3754-3768.
[12]	SHAFIEIRAD H , ADVE R S , SHAHBAZPANAHI S . Throughput maximization with an energy outage constraint for energy harvesting links[C]// 2017 IEEE Wireless Communications and Networking Conference Workshops. Piscataway:IEEE Press, 2017: 1-6.
[13]	GURAKAN B , OZEL O , YANG J ,et al. Energy cooperation in energy harvesting communications[J]. IEEE Transactions on Communications, 2013,61(12): 4884-4898.
[14]	GURAKAN B , OZEL O , YANG J ,et al. Energy cooperation in energy harvesting two-way communications[C]// 2013 IEEE International Conference on Communications. Piscataway:IEEE Press, 2013: 3126-3130.
[15]	GURAKAN B , OZEL O , ULUKUS S . Optimal energy routing in networks with energy cooperation[C]// 2014 48th Asilomar Conference on Signals,Systems and Computers. Piscataway:IEEE Press, 2014: 1683-1687.
[16]	GURAKAN B , OZEL O , ULUKUS S . Optimal energy and data routing in networks with energy cooperation[J]. IEEE Transactions on Wireless Communications, 2016,15(2): 857-870.
[17]	AMMAR A , REYNOLDS D . Energy harvesting networks:energy versus data cooperation[J]. IEEE Communications Letters, 2018,22(10): 2128-2131.
[18]	MAMPILLY A V , BHASHYAM S . On the capacity of the half-duplex MIMO Gaussian diamond channel[C]// 2016 International Symposium on Information Theory and Its Applications. Piscataway:IEEE Press, 2016: 728-732.
[19]	GURAKAN B , ULUKUS S . Cooperative diamond channel with energy harvesting nodes[J]. IEEE Journal on Selected Areas in Communications, 2016,34(5): 1604-1617.
[20]	孙莉, 李陶深, 王哲 . 能量收集和能量协作菱形信道的功率分配策略[J]. 小型微型计算机系统, 2020,41(3): 569-574.
	SUN L , LI T S , WANG Z . Power allocation strategy for energy harvesting and energy cooperation diamond channels[J]. Journal of Chi nese Computer Systems, 2020,41(3): 569-574.
[21]	TUTUNCUOGLU K , YENER A . Energy harvesting networks with energy cooperation:procrastinating policies[J]. IEEE Transactions on Communications, 2015,63(11): 4525-4538.
[22]	NI W H , DONG X D . Energy harvesting wireless communications with energy cooperation between transmitter and receiver[J]. IEEE Transactions on Communications, 2015,63(4): 1457-1469.
[23]	SHIN D K , CHOI W , KIM D I . The two-user Gaussian interference channel with energy harvesting transmitters:energy cooperation and achievable rate region[J]. IEEE Transactions on Communications, 2015,63(11): 4551-4564.
[24]	DONG Y Q , CHEN Z C , FAN P Y . Capacity region of Gaussian multiple-access channels with energy harvesting and energy cooperation[J]. IEEE Access, 2017,5: 1570-1578.
[25]	SU N M , KAYA O , KOCA M . Energy harvesting cooperative multiple access under energy storage losses[C]// 2017 25th Signal Processing and Communications Applications Conference. Piscataway:IEEE Press, 2017: 1-4.
[26]	GAUTAM S , LAGUNAS E , SHARMA S K ,et al. Relay selection strategies for SWIPT-enabled cooperative wireless systems[C]// 2017 IEEE 28th Annual International Symposium on Personal,Indoor,and Mobile Radio Communications. Piscataway:IEEE Press, 2017: 1-7.

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