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Tsinghua Science and Technology 2018, 23(4): 406-418 https://doi.org/10.26599/TST.2018.9010034
Open Access | Issue | Published: 16 August 2018

An Efficient EH-WSN Energy Management Mechanism

Show Author's Information Yang Zhang Hong Gao( ) Siyao Cheng Jianzhong Li
Department of Computer Science and Technology, Harbin Institute of Technology, Harbin 150001, China.
Department of Key Laboratory of Mechatronics, Heilongjiang University, Harbin 150080, China.
Keywords:
energy efficiency, energy harvesting WSN, energy measurement, synchronous wakeup
Cite this article:
Zhang Y, Gao H, Cheng S, et al. An Efficient EH-WSN Energy Management Mechanism. Tsinghua Science and Technology, 2018, 23(4): 406-418. https://doi.org/10.26599/TST.2018.9010034
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Abstract Full text About this article

An Energy-Harvesting Wireless Sensor Network (EH-WSN) depends on harvesting energy from theenvironment to prolong network lifetime. Subjected to limited energy in complex environments, an EH-WSN encounters difficulty when applied to real environments as the network efficiency is reduced. Existing EH-WSN studies are usually conducted in assumed conditions in which nodes are synchronized and the energy profile is knowable or calculable. In real environments, nodes may lose their synchronization due to lack of energy. Furthermore, energy harvesting is significantly affected by multiple factors, whereas the ideal hypothesis is difficult to achieve in reality. In this paper, we introduce a general Intermittent Energy-Aware (IEA) EH-WSN platform. For the first time, we adopted a double-stage capacitor structure to ensure node synchronization in situations without energy harvesting, and we used an integrator to achieve ultra-low power measurement. With regard to hardware and software, we provided an optimized energy management mechanism for intermittent functioning. This paper describes the overall design of the IEA platform, and elaborates the energy management mechanism from the aspects of energy management, energy measurement, and energy prediction. In addition, we achieved node synchronization in different time and energy environments, measured the energy in reality, and proposed the light weight energy calculation method based on measured solar energy. In real environments, experiments are performed to verify the high performance of IEA in terms of validity and reliability. The IEA platform is shown to have ultra-low power consumption and high accuracy for energy measurement and prediction.


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About this article

An Efficient EH-WSN Energy Management Mechanism

Show Author's information Yang ZhangHong Gao( )Siyao ChengJianzhong Li
Department of Computer Science and Technology, Harbin Institute of Technology, Harbin 150001, China.
Department of Key Laboratory of Mechatronics, Heilongjiang University, Harbin 150080, China.

Abstract

An Energy-Harvesting Wireless Sensor Network (EH-WSN) depends on harvesting energy from theenvironment to prolong network lifetime. Subjected to limited energy in complex environments, an EH-WSN encounters difficulty when applied to real environments as the network efficiency is reduced. Existing EH-WSN studies are usually conducted in assumed conditions in which nodes are synchronized and the energy profile is knowable or calculable. In real environments, nodes may lose their synchronization due to lack of energy. Furthermore, energy harvesting is significantly affected by multiple factors, whereas the ideal hypothesis is difficult to achieve in reality. In this paper, we introduce a general Intermittent Energy-Aware (IEA) EH-WSN platform. For the first time, we adopted a double-stage capacitor structure to ensure node synchronization in situations without energy harvesting, and we used an integrator to achieve ultra-low power measurement. With regard to hardware and software, we provided an optimized energy management mechanism for intermittent functioning. This paper describes the overall design of the IEA platform, and elaborates the energy management mechanism from the aspects of energy management, energy measurement, and energy prediction. In addition, we achieved node synchronization in different time and energy environments, measured the energy in reality, and proposed the light weight energy calculation method based on measured solar energy. In real environments, experiments are performed to verify the high performance of IEA in terms of validity and reliability. The IEA platform is shown to have ultra-low power consumption and high accuracy for energy measurement and prediction.

Keywords: energy efficiency, energy harvesting WSN, energy measurement, synchronous wakeup

References(31)

[1]
Z. B. Zhou, W. Fang, J. W. Niu, L. Shu, and M. Mukherjee, Energy-efficient event determination in underwater WSNs leveraging practical data prediction, IEEE Trans. Ind. Inf., vol. 13, no. 3, pp. 1238-1248, 2017.
DOI Google Scholar
[2]
T. Shi, S. Y. Cheng, Z. P. Cai, Y. S. Li, and J. Z. Li, Exploring connected dominating sets in energy harvest networks, IEEE/ACM Trans. Netw., vol. 25, no. 3, pp. 1803-1817, 2017.
DOI Google Scholar
[3]
J. G. Yu, Y. Chen, L. R. Ma, B. G. Huang, and X. Z. Cheng, On connected target k-coverage in heterogeneous wireless sensor networks, Sensors (Basel), vol. 16, no. 1, p. E104, 2016.
DOI Google Scholar
[4]
J. Li, S. Y. Cheng, Z. Cai, J. G. Yu, C. K. Wang, and Y. S. Li, Approximate holistic aggregation in wireless sensor networks, ACM Trans. Sensor Netw. (TOSN), vol. 13, no. 2, p. 11, 2017.
DOI Google Scholar
[5]
C. Aranzazu-Suescun and M. Cardei, Distributed algorithms for event reporting in mobile-sink WSNs for internet of things, Tsinghua Sci. Technol., vol. 22, no. 4, pp. 413-426, 2017.
DOI Google Scholar
[6]
S. Y. Cheng, Z. P. Cai, J. Z. Li, and H. Gao, Extracting kernel dataset from big sensory data in wireless sensor networks, IEEE Trans. Knowl. Data Eng., vol. 29, no. 4, pp. 813-827, 2017.
DOI Google Scholar
[7]
T. Qiu, A. Y. Zhao, R. X. Ma, V. Chang, F. B. Liu, and Z. J. Fu, A task-efficient sink node based on embedded multi-core SoC for internet of things, Future Generation Comput. Syst., vol. 82, pp. 656-666, 2018.
DOI Google Scholar
[8]
X. Zheng, Z. P. Cai, J. Z. Li, and H. Gao, A study on application-aware scheduling in wireless networks, IEEE Trans. Mob. Comput., vol. 16, no. 7, pp. 1787-1801, 2017.
DOI Google Scholar
[9]
Z. B. Chen, A. F. Liu, Z. T. Li, Y. J. Choi, H. Sekiya, and J. Li, Energy-efficient broadcasting scheme for smart industrial wireless sensor networks, Mobile Information Systems, vol. 2017, p. 7538190, 2017.
DOI Google Scholar
[10]
S. Y. Cheng, Z. P. Cai, and J. Z. Li, Curve query processing in wireless sensor networks, IEEE Trans. Veh. Technol., vol. 64, no. 11, pp. 5198-5209, 2015.
DOI Google Scholar
[11]
C. Park and P. H. Chou, AmbiMax: Autonomous energy harvesting platform for multi-supply wireless sensor nodes, in Proc. 3@rd Ann. IEEE Communications Society on Sensor and Ad Hoc Communications and Networks, Reston, VA, USA, 2007, pp. 168-177.
DOI
[12]
M. Gorlatova, R. Margolies, J. Sarik, G. Stanje, J. X. Zhu, B. Vigraham, M. Szczodrak, L. Carloni, P. Kinget, I. Kymissis, et al., Prototyping energy harvesting active networked tags (EnHANTs), in Proc. IEEE INFOCOM, Turin, Italy, 2013, pp. 585-589.
DOI
[13]
M. Buettner, B. Greenstein, and D. Wetherall, Dewdrop: An energy-aware runtime for computational RFID, in Proc. 8@th Usenix Conf. Networked Systems Design and Implementation, Boston, MA, USA, 2011, pp. 197-210.
[14]
L. Feng, J. G. Guo, F. Zhao, and H. L. Jiang, A novel analysis of delay and power consumption for polling schemes in the IoT, Tsinghua Sci. Technol., vol. 22, no. 4, pp. 368-378, 2017.
DOI Google Scholar
[15]
Z. B. Chen, A. F. Liu, Z. T. Li, Y. J. Choi, and J. Li, Distributed duty cycle control for delay improvement in wireless sensor networks, Peer-to-Peer Netw. Appl., vol. 10, no. 3, pp. 559-578, 2017.
DOI Google Scholar
[16]
T. Qiu, R. X. Qiao, and D. O. Wu, EABS: An event-aware backpressure scheduling scheme for emergency internet of things, IEEE Trans. Mob. Comput., vol. 17, no. 1, pp. 72-84, 2018.
DOI Google Scholar
[17]
A. F. Liu, Q. Zhang, Z. T. Li, Y. J. Choi, L. Jie, and N. Komuro, A green and reliable communication modeling for industrial internet of things, Comput. Electr. Eng., vol. 58, pp. 364-381, 2017.
DOI Google Scholar
[18]
T. Shi, S. Y. Cheng, Z. P. Cai, and J. Z. Li, Adaptive connected dominating set discovering algorithm in energy-harvest sensor networks, in Proc. 35@th Ann. IEEE Int. Conf. Computer Communications, San Francisco, CA, USA, 2016, pp. 1-9.
DOI
[19]
C. M. Vigorito, D. Ganesan, and A. G. Barto, Adaptive control of duty cycling in energy-harvesting wireless sensor networks, in Proc. 4@th Ann. IEEE Communications Society Conf. Sensor, Mesh and Ad Hoc Communications and Networks, San Diego, CA, USA, 2007, pp. 21-30.
DOI
[20]
X. J. Ren and W. F. Liang, Delay-tolerant data gathering in energy harvesting sensor networks with a mobile sink, in Proc. 2012 IEEE Global Communications Conf., Anaheim, CA, USA, 2013, pp. 93-99.
[21]
X. L. Wang, J. Gong, C. S. Hu, S. Zhou, and Z. S. Niu, Optimal power allocation on discrete energy harvesting model, EURASIP J. Wireless Commun. Netw., vol. 2015, no. 1, p. 48, 2015.
DOI Google Scholar
[22]
K. Nakayama, N. Dang, L. Bic, M. Dillencourt, E. Bozorgzadeh, and N. Venkatasubramanian, Distributed flow optimization control for energy-harvesting wireless sensor networks, in Proc. 2014 IEEE Int. Conf. Communications, Sydney, Australia, 2014, pp. 4083-4088.
DOI
[23]
X. J. Ren, W. F. Liang, and W. Z. Xu, Quality-aware target coverage in energy harvesting sensor networks, IEEE Trans. Emerg. Top. Comput., vol. 3, no. 1, pp. 8-21, 2015.
DOI Google Scholar
[24]
J. R. Smith, A. P. Sample, P. S. Powledge, S. Roy, and A. Mamishev, A wirelessly-powered platform for sensing and computation, in Proc. 8@th Int. Conf. Ubiquitous Computing, Orange County, CA, USA, 2006, pp. 495-506.
DOI
[25]
M. Hassanalieragh, T. Soyata, A. Nadeau, and G. Sharma, UR-SolarCap: An open source intelligent auto-wakeup solar energy harvesting system for supercapacitor-based energy buffering, IEEE Access, vol. 4, pp. 542-557, 2016.
DOI Google Scholar
[26]
S. Y. Cheng, J. Z. Li, and L. Yu, Location aware peak value queries in sensor networks, in Proc. 2012 IEEE INFOCOM, 2012, pp. 486-494.
DOI
[27]
S. Y. Cheng, Z. P. Cai, J. Z. Li, and X. L. Fang, Drawing dominant dataset from big sensory data in wireless sensor networks, in Proc. 2015 IEEE Conf. Computer Communications, Hong Kong, China, 2015, pp. 531-539.
DOI
[28]
J. Z. Li, S. Y. Cheng, H. Gao, and Z. P. Cai, Approximate physical world reconstruction algorithms in sensor networks, IEEE Trans. Parallel Distrib. Syst., vol. 25, no. 12, pp. 3099-3110, 2014.
DOI Google Scholar
[29]
R. Shigeta, T. Sasaki, D. M. Quan, Y. Kawahara, R. J. Vyas, M. M. Tentzeris, and T. Asami, Ambient RF energy harvesting sensor device with capacitor-leakage-aware duty cycle control, IEEE Sens.J., vol. 13, no. 8, pp. 2973-2983, 2013.
DOI Google Scholar
[30]
Y. Zhang, H. Gao, S. Y. Cheng, Z. P. Cai, and J. Z. Li, IEA: An intermittent energy aware platform for ultra-low powered energy harvesting WSN, in Proc. 12@th Int. Conf. Wireless Algorithms, Systems, and Appl., 2017, pp. 185-197.
DOI
[31]
D. H. Jung, K. Kim, and S. O. Jung, Thermal and solar energy harvesting boost converter with time-multiplexing MPPT algorithm, IEICE Electron. Express, vol. 13, no. 12, p. 20160287, 2016.
DOI Google Scholar
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Publication history

Received: 11 September 2017
Accepted: 18 September 2017
Published: 16 August 2018
Issue date: August 2018

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© The authors 2018

Acknowledgements

This work was supported in part by the Key Program of National Natural Science Foundation of China (No. 61632010), and Harbin Municipal Science and Technology Innovation Talent Research Funded Project (No. 2014RFQXJ027).

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