An intelligent solar energy-harvesting system for wireless sensor networks

Eurasip Journal on Wireless Communications and Networking

Volumn 2015, Issue 1, 2015, Pages 1-12

  Li, Yin ^a   Shi, Ronghua ^a  

^a CENTRAL SOUTH UNIVERSITY   (China)

Author keywords

Bimodule power supply; Internet of Things; MPPT; Solar energy harvesting; WSN

Indexed keywords

ELECTRIC BATTERIES; ELECTRONIC CIRCUIT TRACKING; INTERNET; INTERNET OF THINGS; LITHIUM; LITHIUM BATTERIES; MAXIMUM POWER POINT TRACKERS; RECONFIGURABLE HARDWARE; SECONDARY BATTERIES; SENSOR NODES; SOFTWARE RELIABILITY; SOLAR ENERGY; SYSTEM STABILITY; WIRELESS SENSOR NETWORKS;

CHARGE-DISCHARGE CYCLE; CONTROL CIRCUITS; INTERNET OF THING (IOT); MAXIMUM POWER POINT TRACKING; POWER EQUIPMENT; POWER SUPPLY; RELIABILITY AND STABILITY; WIRELESS SENSOR NODE;

ENERGY HARVESTING;

EID: 84957538256     PISSN: 16871472     EISSN: 16871499     Source Type: Journal    
DOI: 10.1186/s13638-015-0414-2     Document Type: Article

References (38)

1. ZhouY, Yang X, Guo X, et al. A design of greenhouse monitoring & control system based on ZigBee wireless sensor network. IEEE. Int. Conf. WiCOM, (IEEE, Shanghai, 2007), pp. 2563–2567
2. Ahonen T, Virrankoski R, Elmusrati M. Greenhouse monitoring with wireless sensor network. IEEE/ASME. Int. Conf. on MESA, (IEEE/ASME, Beijing, 2008), pp. 403–408
3. Nasser N, Zaman A, Karim L, et al. CPWS: An efficient routing protocol for RGB sensor-based fish pond monitoring system. IEEE. 8th. Int. Conf. WiMob, (IEEE, Barcelona, 2012), pp. 7–11
4. O’Flyrm B, Martinez R, Cleary J, et al. Smart Coast: a wireless sensor network for water quality monitoring. IEEE. 32nd. Conf. LCN. 2007;815–816.
5. GS Arumugam, T Ponnuchamy, EE-LEACH: development of energy-efficient LEACH Protocol for data gathering in WSN. EURASIP. J. Wireless. Commun. Netw. 1, 76 (2015). doi:10.1186/s13638-015-0306-5
6. I Butun, I Ra, R Sankar, PCAC: power-and connectivity-aware clustering for wireless sensor Networks. EURASIP. J. Wireless. Commun. Net. 1, 83 (2015). doi:10.1186/s13638-015-0321-6
7. G Anastasi, M Conti, M Di Francesco et al., Energy conservation in wireless sensor networks: a survey. Ad. Hoc. Netw. 7(3), 537–568 (2009)
8. RJM Vullers, RV Schaijk, HJ Visser et al., Energy harvesting for autonomous wireless sensor networks. IEEE. Solid State Circuits. Mag. 2(2), 29–38 (2010)
9. F Akhtar, MH Rehmani, Energy replenishment using renewable and traditional energy resources for sustainable wireless sensor networks: a review. Renew. Sustain. Energy Rev. 45, 769–784 (2015)
10. VA Boicea, Energy storage technologies: the past and the present. Proc. IEEE. 102(11), 1777–1794 (2014)
11. Z Xu et al., Electrochemical supercapacitor electrodes from sponge-like graphenenano architectures with ultrahigh power density. J. Phys. Chem. Lett. 3(20), 2928–2933 (2012)
12. W Waag, S Käbitz, DU Sauer, Experimental investigation of the lithium-ion battery impedance characteristic at various conditions and aging states and its influence on the application. Appl. Energy. 102, 885–897 (2013)
13. M Broussely, P Biensan, F Bonhomme et al., Main aging mechanisms in Li ion batteries. J. Power. Sources. 146(1), 90–96 (2005)
14. J Vetter, P Novák, MR Wagner et al., Ageing mechanisms in lithium-ion batteries. J. Power. Sources. 147(1), 269–281 (2005)
15. M Ecker, JB Gerschler, J Vogel et al., Development of a lifetime prediction model for lithium-ion batteries based on extended accelerated aging test data. J. Power. Sources. 215, 248–257 (2012)
16. Jiang X, Polastre J, Culler D. Perpetual environmentally powered sensor networks. IEEE. 4th. Int Symp. IPSN, (IEEE, Los Angeles, 2005), pp. 463–468
17. Xiang Y, Pasricha S. Run-time management for multicore embedded systems with energy harvesting. 2015. doi:10.1109/TVLSI.2014.2381658
18. Dutta P, Hui J, Jeong J, et al. Trio: enabling sustainable and scalable outdoor wireless sensor network deployments. Proc. 5th. Int. Conf. Info. Process. Sensor. Netw, (ACM, Nashville, TN, 2006), pp. 407–415
19. A Berger, LB Hörmann, C Leitner et al., Sustainable energy harvesting for robust wireless sensor networks in industrial applications (Sensor Applications Symposium SAS, Zadar, 2015)
20. Dall’Ora R, Raza U, Brunelli D, et al. SensEH: From simulation to deployment of energy harvesting wireless sensor networks. IEEE. 39th. Conf. Local. Comput. Netw. Workshops, (IEEE, Edmonton, AB, 2014), pp. 566–573
21. V Sharma, U Mukherji, V Joseph et al., Optimal energy management policies for energy harvesting sensor nodes. IEEE. Trans. Wireless. Commun. 9(4), 1326–1336 (2010)
22. Ramasur D, Hancke G P. A wind energy harvester for low power wireless sensor networks. IEEE. Int. Conf. I2MTC, (IEEE, Graz, 2012), pp. 2623–2627
23. JA Khan, HK Qureshi, A Iqbal, Energy management in wireless sensor networks: a survey. Comput. Electr. Eng. 41, 159–176 (2015)
24. Y Gao, G Sun, W Li et al., Wireless sensor node design based on solar energy supply. IEEE. 2nd. Int. Conf. PEITS 3, 203–207 (2009)
25. Naveen K V, Manjunath S S. A reliable ultra-capacitor based solar energy harvesting system for wireless sensor network enabled intelligent buildings. IEEE. 2nd. Int. Conf. IAMA, (IEEE, Chennai, 2011), pp. 20–25
26. Chuang WY, Lee CH, Lin CT, et al. Self-sustain wireless sensor module. IEEE Int Conf Internet Things Green Computing Commun Cyber Physical Soc Computing 2014;288–291
27. Taneja J, Jeong J, Culler D. Design, modeling, and capacity planning for micro-solar power sensor networks. Proc. 7th. IEEE. Int. Conf. IPSN, (IEEE Computer Society, St. Louis, Missouri, 2008), pp. 407–418
28. Alberola J, Pelegri J, Lajara R, et al. Solar inexhaustible power source for wireless sensor node. IEEE. Proc. IMTC, (IEEE, Victoria, BC, 2008), pp. 657–662
29. Bhuvaneswari P T V, Balakumar R, Vaidehi V, et al. Solar energy harvesting for wireless sensor networks. IEEE. 1st. Int. Conf. CICSYN, (IEEE, Indore, 2009), pp. 57–61
30. Isaacson M J, Holl. Sworth R P, Giampaoli P J, et al. Advanced lithium ion battery charger. IEEE. 15th. BCAA, (IEEE, Long Beach, CA, 2000), pp. 193–198
31. F Ongaro, S Saggini, P Mattavelli, Li-ion battery-supercapacitor hybrid storage system for a long lifetime photovoltaic-based wireless sensor network. IEEE. Trans. Power. Electronics. 27(9), 3944–3952 (2012)
32. H He, R Xiong, X Zhang et al., State-of-charge estimation of the lithium-ion battery using an adaptive extended Kalman filter based on an improved Thevenin model. IEEE. Trans. Veh. Technol. 60(4), 1461–1469 (2011)
33. K Takahashi, M Saitoh, N Asakura et al., Electrochemical properties of lithium manganese oxides with different surface areas for lithium ion batteries. J. Power. Sources. 136(1), 115–121 (2004)
34. YJ Liu, XH Li, HJ Guo et al., Electrochemical performance and capacity fading reason of LiMn2O4/graphite batteries stored at room temperature. J. Power. Sources. 189(2), 721–725 (2009)
35. X Li, Y Wu, G Li et al., Development of wireless soil moisture sensor base on solar energy. Trans. CSAE. 26(11), 13–18 (2010)
36. D Brunelli, C Moser, L Thiele et al., Design of a solar-harvesting circuit for batteryless embedded systems. IEEE. Trans. Circuits. Syst I: Regul. Pap. 56(11), 2519–2528 (2009)
37. T Esram, PL Chapman, Comparison of photovoltaic array maximum power point tracking techniques. IEEE. Trans. Energy. Conversion. EC. 22(2), 439 (2007)
38. CN3063 datasheet, Shanghai Consonance Electronics Co. Ltd., http://www.consonance-elec.com/pdf/datasheet/DSE-CN3063.pdf.