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This work was supported in part by Key Program of National Natural Science Foundation of China (Grant No. 61933002).
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[1] Ha M, Lim S, Ko H. Wearable and flexible sensors for user-interactive health-monitoring devices. J Mater Chem B, 2018, 6: 4043-4064 CrossRef Google Scholar
[2] Yang G, Tan W, Jin H. Review wearable sensing system for gait recognition. Cluster Comput, 2019, 22: 3021-3029 CrossRef Google Scholar
[3] Deng F, Qiu H, Chen J, et al. Wearable thermoelectric power generators combined with flexible supercapacitor for low-power human diagnosis devices. IEEE Transactions on industrial electronics, 2016, 64(2): 1477-1485. Google Scholar
[4] Li Y, Deng F. Modeling and simulation of thermoelectric power generation system based on finite element method. In: Proceedings of the 33rd Chinese Control Conference, 2014. 6388--6393. Google Scholar
[5] Gui P, Deng F, Liang Z. Micro linear generator for harvesting mechanical energy from the human gait. Energy, 2018, 154: 365-373 CrossRef Google Scholar
[6] Ding N, Deng F, Cai Y, et al. Wearable human foot mechanical energy harvesting device based on moving-coil generator. In: Proceedings of 2019 Chinese Control Conference (CCC), 2019. 6498--6503. Google Scholar
[7] Deng F, Cai Y, Fan X. Pressure-type generator for harvesting mechanical energy from human gait. Energy, 2019, 171: 785-794 CrossRef Google Scholar
[8] Fan X, Deng F, Chen J. Voltage band analysis for maximum power point tracking of stand-alone PV systems. Sol Energy, 2017, 144: 221-231 CrossRef ADS Google Scholar
[9] Xie W, Huang G, Zhang X, et al. A maximum power point tracking controller for thermoelectric generators. In: Proceedings of 2017 36th Chinese Control Conference (CCC), 2017. 9079--9084. Google Scholar
Figure 1
(Color online) Ubiquitous energy harvesting devices. (a) Solar energy harvesting device; (b) thermal energy harvesting device; (c) foot mechanical energy harvesting device.
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