Collaborative Energy and Information Transfer in Green Wireless Sensor Networks for Smart Cities

Smart city is able to make the city source and infrastructure more efficiently utilized, which improves the quality of life for citizens. In this framework, wireless sensor networks (WSNs) play an important role to collect, process, and analyze the corresponding information. However, the massive deployment of WSNs consumes a significant energy consumption, which has raised the growing demand for green WSNs for smart cities. Exploiting the recent advance in collaborative energy and information transfer to power the WSNs and transmit the data has been considered a promising approach to realize the green WSNs for smart cities. We propose an architecture design of the green WSNs for smart cities, by exploiting the collaborative energy and information transfer protocol, and illustrate the challenging issues in this design. To achieve a green system design, the sensor nodes in WSNs harvest the energy simultaneously with the information decoding (ID) from the received radio frequency signals. Specifically, the energy-constrained sensor nodes partition the received signals into two independent groups to perform energy harvesting (EH) and ID. The sensor nodes then use the harvested energy to amplify and forward the information signals. We study the joint optimization of subcarrier grouping, subcarrier pairing, and power allocation such that the transmission rate performance is maximized with the EH constraint. The joint optimization problem is solved via dual decomposition after transforming it into an equivalent convex optimization problem. Simulation results tested with the real WSNs system data indicate that the performance of our proposed protocol can be significantly improved.

[1]  Sabato Manfredi,et al.  Decentralized Control Algorithm for Fast Monitoring and Efficient Energy Consumption in Energy Harvesting Wireless Sensor Networks , 2017, IEEE Transactions on Industrial Informatics.

[2]  Yue Zhang,et al.  Sensing and Classifying Roadway Obstacles in Smart Cities: The Street Bump System , 2016, IEEE Access.

[3]  Abraham O. Fapojuwo,et al.  Radio Frequency Energy Harvesting and Data Rate Optimization in Wireless Information and Power Transfer Sensor Networks , 2017, IEEE Sensors Journal.

[4]  Abbas Mehrabi,et al.  General Framework for Network Throughput Maximization in Sink-Based Energy Harvesting Wireless Sensor Networks , 2017, IEEE Transactions on Mobile Computing.

[5]  T. O'Donnell,et al.  Energy scavenging for long-term deployable wireless sensor networks. , 2008, Talanta.

[6]  Christian Bettstetter,et al.  An Experimental Study of Selective Cooperative Relaying in Industrial Wireless Sensor Networks , 2014, IEEE Transactions on Industrial Informatics.

[7]  J. Millard,et al.  Mapping Smart Cities in the EU , 2014 .

[8]  Luca Benini,et al.  Adaptive Rectifier Driven by Power Intake Predictors for Wind Energy Harvesting Sensor Networks , 2015, IEEE Journal of Emerging and Selected Topics in Power Electronics.

[9]  Carlo Ratti,et al.  Real-Time Urban Monitoring Using Cell Phones: A Case Study in Rome , 2011, IEEE Transactions on Intelligent Transportation Systems.

[10]  Brian Vad Mathiesen,et al.  Smart Energy Systems for coherent 100% renewable energy and transport solutions , 2015 .

[11]  Xiaodong Wang,et al.  A Cooperative SWIPT Scheme for Wirelessly Powered Sensor Networks , 2017, IEEE Transactions on Communications.

[12]  Victor C. M. Leung,et al.  Optimal Transmission Policies for Relay Communication Networks With Ambient Energy Harvesting Relays , 2016, IEEE Journal on Selected Areas in Communications.

[13]  Yuanyuan Yang,et al.  Energy-Efficient Cooperative Tfor Simultaneous Wireless Information and Power Transfer in Clustered Wireless Sensor Networks , 2015, IEEE Transactions on Communications.

[14]  Taskin Koçak,et al.  Smart Grid Technologies: Communication Technologies and Standards , 2011, IEEE Transactions on Industrial Informatics.

[15]  Roberto Di Pietro,et al.  Smart health: A context-aware health paradigm within smart cities , 2014, IEEE Communications Magazine.

[16]  Wei Yu,et al.  Dual methods for nonconvex spectrum optimization of multicarrier systems , 2006, IEEE Transactions on Communications.

[17]  Jianwei Huang,et al.  Energy-Aware Cooperative Traffic Offloading via Device-to-Device Cooperations: An Analytical Approach , 2017, IEEE Transactions on Mobile Computing.

[18]  Zhiguo Ding,et al.  Performance Analysis and Optimization for SWIPT Wireless Sensor Networks , 2017, IEEE Transactions on Communications.

[19]  Xingcheng Liu,et al.  Reliable Cooperative Communications Based on Random Network Coding in Multi-Hop Relay WSNs , 2014, IEEE Sensors Journal.

[20]  Kyoung-Jae Lee,et al.  Simultaneous Wireless Information and Power Transfer for Cooperative Relay Networks With Battery , 2017, IEEE Access.

[21]  Alagan Anpalagan,et al.  Efficient Wireless Power Transfer in Software-Defined Wireless Sensor Networks , 2016, IEEE Sensors Journal.

[22]  Bo Wang,et al.  Wireless Information and Power Transfer to Maximize Information Throughput in WBAN , 2017, IEEE Internet of Things Journal.

[23]  Yuzhen Huang,et al.  Joint Robust Design for Secure AF Relay Networks With SWIPT , 2017, IEEE Access.

[24]  Bin Xiao,et al.  Energy-Efficient Cooperative Transmission for Simultaneous Wireless Information and Power Transfer in Clustered Wireless Sensor Networks , 2017 .

[25]  Lav R. Varshney,et al.  Transporting information and energy simultaneously , 2008, 2008 IEEE International Symposium on Information Theory.

[26]  Sambit Bakshi,et al.  Direction Estimation for Pedestrian Monitoring System in Smart Cities: An HMM Based Approach , 2016, IEEE Access.

[27]  José Ramón Gil-García,et al.  Understanding Smart Cities: An Integrative Framework , 2012, HICSS.

[28]  Miguel Azenha,et al.  Optimal behavior of responsive residential demand considering hybrid phase change materials , 2016 .