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Title: Compute-proximal Energy Harvesting for Mobile Environments: Fundamentals, Applications, and Tools
Jung Wook Park
Ph.D. Student, Computer Science
School of Interactive Computing
Georgia Institute of Technology
Date: Tuesday, February 23, 2021
Time: 12:00 PM – 2:00 PM (EST)
Location (Remote via BlueJeans): https://gatech.bluejeans.com/4043881358
Committee:
Dr. Gregory D. Abowd (Co-Advisor), School of Interactive Computing, Georgia Institute of Technology
Dr. Rosa I. Arriaga (Co-Advisor), School of Interactive Computing, Georgia Institute of Technology
Dr. W. Keith Edwards, School of Interactive Computing, Georgia Institute of Technology
Dr. Thad E. Starner, School of Interactive Computing, Georgia Institute of Technology
Dr. HyunJoo Oh, School of Interactive Computing & School of Industrial Design, Georgia Institute of Technology
Dr. Abdelsalam (Sumi) Helal, Department of Computer & Information Science & Engineering, University of Florida
Abstract:
Over the past two decades, we have witnessed remarkable achievements in computing, sensing, actuating, and communications capabilities of ubiquitous computing applications. However, due to the limitations in stable energy supply, it is still challenging to make the applications ubiquitous. Two key techniques—energy harvesting and power management—have been studied as an alternative to overcome the battery limitations. Compared to static environments such as homes or buildings, there would be more energy harvesting opportunities in mobile environments as ubiquitous systems can generate various forms of energy as they move. Most of the previous studies in this regard have been focused on human movements for wearable computing, and other mobile environments have received limited attention.
In this thesis proposal, I present a class of energy harvesting approaches called compute-proximal energy harvesting, which allows us to consider developing energy harvesting hardware where computing, sensing, and actuating are needed in other mobile environments. Computing includes sensing phenomena, executing instructions, actuating components, storing information, or communication. Proximal indicates the consideration of harvesting energy available around the specific location where there is a need for computation, reducing the need for excessive wiring. A primary goal of this new approach is to mitigate the effort associated with the installation and field deployment of self-sustained computing and further lower the barriers to entry for developing self-sustainable systems for mobile systems. In this proposal, I select an automobile as a promising case study and discuss the opportunities, challenges, and design guidelines of compute-proximal energy harvesting with practical yet advanced examples in the automotive domain. In addition, I propose one additional study to extend the lessons learned from the automotive case studies for other researchers or makers. In this study, I seek to understand what problems they have encountered and what possible solutions they have considered while dealing with energy harvesting technology. Based on the findings, I will develop a comprehensive energy harvesting toolkit and examine its utility and usefulness through a series of user studies.
