资源描述
南 京 航 空 航 天 大 学 攻读硕士学位硕士
课 题 论 证 报 告
姓 名
学 号
专 业
研究方向
指导教师
2023年 12月 10日
1
2
3
4
5
6
7
8
9
参 考 文 献 (应 有 20 篇 以 上 [1] 贺学锋,李江,赵兴强,温志渝,王晓兰.带质量块旳微型压电式风能采集器研究[J].传感技术 学报 2023,24(7) :986-989. [2] Yen Kheng Tan. Self-Autonomous Wireless Sensor Nodes With Wind Energy Harvesting for Remote Sensing of Wind-Driven Wildfire Spread [J].IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT,2023,60(4:1367-1377. [3] Yen Kheng Tan. Optimized Wind Energy Harvesting System Using Resistance Emulator and Active Rectifier for Wireless Sensor Nodes [J]. IEEE TRANSACTIONS ON POWER ELECTRONICS,2023,26(1,38-50. [4] Emilio Sardini. Self-Powered Wireless Sensor for Air Temperature and Velocity Measurements With Energy Harvesting Capability [J]. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT,2023,60(5:1838-1844. [5] M. A. Weimer, T. S. Paing, and R. A. Zane.Remote area wind energy harvesting for low-power autonomous sensors[J].in Proc. Power Electron.Spec. Conf, 2023, 1-5. [6] P. D. Mitcheson, E. M. Yeatman, G. K. Rao, A. S. Holmes, and T. C. Green. Energy harvesting from human and machine motion for wireless electronic devices[J]. Proc. IEEE, 2023 ,96 (9,1457–1486. [7] H. J. Jung, S. W. Lee, and D. D. Jang. Feasibility study on a new energy harvesting electromagnetic device using aerodynamic instability[J].IEEE Trans. Magn,vol. 2023 ,45(10 , 4376–4379. [8] C. Vlad, I. Munteanu, A. I. Bratcu, and E. Ceanga.Output power maximization of low-power wind energy conversion systems revisited: Possible control solutions[J].Energy Convers. Manage, 2023,51(2, 305–310. [9] E. Sardini and M. Serpelloni.Passive and self-powered autonomous sensors for remote measurements[J]. 2023,9(2, 1–18. [10] D. Marioli, A. Flammini, E. Sardini, and M. Serpelloni.An autonomous sensor with energy harvesting capability for airflow speedmeasurements[J]. 2023,892–897. [11] Paul D. Mitcheson,Tim C. Green,Eric M. Yeatman. Architecture for vibration-driven micropower generators. Journal of microelectromechanical systems, 2023: 429-440. [12]P. G. Jones,Tudor,M. J. Beeby. An electromagnetic vibration-powered generator for intelligent sensor systems. Sensors and Actuators A: Physical, 2023: 344-349. [13]Ching, Neil N.H.,Wong, H.Y. A laser-micromachined multi-modal resonating power transducer for wireless sensing systems. Sensors and Actuators A, 2023: 685-690. [14] Zhu, A Reid, S. Finney and M. Judd. Energy Scavenging Technique for Powering Wireless M. 10
Sensors. Proc. International Conference on Condition Monitoring and Diagnosis, 2023: 881-884. [15]G. M. Rebeiz, J. B. Muldavin. RF MEMS Switches and Switch Circuits. IEEE MicroWave Magazine,2023: 59-71. [16]M. Zhu, M. D. Judd and P. J. Moore. Energy Harvesting in Substations for Powering Autonomous Sensors. Sensor Technologies and Applications, 2023: 246 - 251. [17]Dwari, S,Dayal, R. Efficient Direct AC-to-DC Converters for Vibration-Based Low Voltage Energy Harvesting. IECON, Industrial Electronics, 34th Annual Conference of IEEE, 2023: 2320 - 2325. [18]Suman Dwari, Leila Parsa. An Efficient AC–DC Step-Up Converter for Low-Voltage Energy Harvesting. Power Electronics, IEEE Transactions on,2023: 2188-2199. [19]Starzyk, J.A.,Ying-Wei Jan,Fengjing Qiu.A DC-DC charge pump design based on voltage doublers. IEEE Transactions on, Fundamental Theory and Applications, 2023: 350-359. [20]Dobbs, B.G.,Chapman, P.L.A Multiple-Input DC–DC Converter Topology. IEEE, Power Electronics Letters, 2023:6-9. [21]Khaligh, A.,Li, Z. Battery, Ultracapacitor, Fuel Cell, and Hybrid Energy Storage Systems for Electric, Hybrid Electric, Fuel Cell, and Plug-In Hybrid Electric Vehicles: State of the Art. Vehicular Technology, IEEE Transactions on,2023:2806-2814. [ 22 ] Khaligh, A , Peng Zeng , Xiaochun Wu. A Hybrid Energy Scavenging Topology for Human-Powered Mobile Electronics. Industrial Electronics, 34th Annual Conference of IEEE, 2023: 448-453. 11
开 题 报 告 专 家 组 考 核 意 见 (包括专家组提出旳意见和提议,总体考核结论:通过、修改后通过或不通过 专家意见: 总体考核结论:通过。 专家组组员(签字 年 月 日 导 师 意 见 导师(签字) : 年 月 日 系 意 见 负责人(签字) : 年 月 日 学 院 意 见 负责人(签字) : 年 月 日 备 注 12
展开阅读全文
浙ICP备2021020529号-1 | 浙B2-20240490 
