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26D041PAES - Design of Energy Harvesting Systems

Course specification
Course title Design of Energy Harvesting Systems
Acronym 26D041PAES
Study programme Electrical Engineering and Computing
Module Electronics and Digital Systems
Type of study doctoral studies
Lecturer (for classes)
Lecturer/Associate (for practice)
    Lecturer/Associate (for OTC)
      ESPB 9.0 Status elective
      Condition
      The goal The course is designed to provide advanced knowledge and research skills in the design of electronic systems that operate autonomously, without constant reliance on external energy sources. The focus is on the development of technologies that enable the harvesting, conversion, and efficient use of energy from the environment, as well as on their integration into complex electronic systems.
      The outcome Analyze and design systems for energy harvesting and conversion; Understand the principles of wireless energy transfer; Apply renewable energy sources in the design of energy harvesting electronic devices; Design advanced battery charging and management systems. Develop innovative solutions for self-sustaining electronic systems in the fields of IoT, medicine, transportation, and industry.
      Contents
      URL to the subject page http://tnt.etf.bg.ac.rs/~26d041paes/
      URL to lectures https://teams.microsoft.com/l/team/19%3ALKmU492HVLRWilRQ99fe-BIHz61SMFThnsTLu7Evz-U1%40thread.tacv2/conversations?groupId=e16820a3-a060-4670-bc7f-ec18ccc40edf&tenantId=1774ef2e-9c62-478a-8d3a-fd2a495547ba
      Contents of lectures Energy Harvesting and integration with sensors and autonomous devices. WPT: inductive, capacitive, and resonant, applications (medical implants, mobile devices, IoE). Solar, wind, and hydrogen technologies and their application. Mini wind turbines and systems based on hydrogen FC, hybrid PS. Battery charging and energy management systems, BMS, electronic controllers for smart energy management.
      Contents of exercises The teaching is carried out through lectures, seminars, and research projects. Particular importance is given to the independent research work of doctoral students, which is encouraged through the preparation of project assignments and the publication of results in relevant scientific journals and conferences.
      Literature
      1. H. M. A. Fahmy, "Wireless Sensor Networks: Energy Harvesting and Management for Research and Industry", Springer, 2020. (Original title)
      2. A. Triviño-Cabrera, J. M. González-González, J. A. Aguado, "Wireless Power Transfer for Electric Vehicles: Foundations and Design Approach", Springer, 2020. (Original title)
      3. C. T. Rim, C. Mi, "Wireless Power Transfer for Electric Vehicles and Mobile Devices", John Wiley & Sons Ltd, 2017. (Original title)
      4. A. L. Dicks, D. A. J. Rand, "Fuel Cell Systems Explained", Wiley. 2018. (Original title)
      5. R. Xiong, W. Shen, "Advanced Battery Management Technologies for Electric Vehicles", Wiley, 2019. (Original title)
      Number of hours per week during the semester/trimester/year
      Lectures Exercises OTC Study and Research Other classes
      8
      Methods of teaching Lectures, mentoring work. Exercises in the electronics laboratory and on experimental grounds. Seminar work or work at a conference with an oral presentation.
      Knowledge score (maximum points 100)
      Pre obligations Points Final exam Points
      Activites during lectures Test paper
      Practical lessons Oral examination 30
      Projects
      Colloquia
      Seminars 70