• DocumentCode
    1777359
  • Title

    Indoor photovoltaic energy harvesting for mm-scale systems

  • Author

    Teran, Alan ; Dejarld, Matt ; Jinyoung Hwang ; Wootaek Lim ; Joeson Wong ; Blaauw, D. ; Yoonmyung Lee ; Millunchick, Joanna ; Phillips, Jacob

  • Author_Institution
    Electr. Eng. & Comput. Sci., Univ. of Michigan, Ann Arbor, MI, USA
  • fYear
    2014
  • fDate
    22-25 June 2014
  • Firstpage
    251
  • Lastpage
    252
  • Abstract
    Low power electronic circuitry, including wirelessly interconnected sensor nodes, is a transformational technology that can be applied to a broad range of applications. These low power systems still require electrical power, ideally from ambient energy sources. Ambient sources of light can provide sufficient energy for these applications. Stray sunlight is more than adequate, though it is not available in all locations. Indoor lighting may also provide a sufficient energy source, though the characteristics of the spectrum are significantly different than the solar spectrum, where irradiance is confined to a narrower window in the visible spectrum. Energy-autonomous operation in mm-scale sensors have been achieved using photovoltaics based on silicon CMOS [1,2]. Improvements in energy harvesting are necessary to increase the duty cycle of the microsystem and to facilitate wireless transceivers. Photovoltaic cells consisting of materials with larger bandgap energy, such as GaAs, provide a better match to the indoor light spectrum, reducing thermalization losses and increasing power generation. The larger voltage provided by higher bandgap materials such as GaAs can also improve the efficiency of the overall system, where higher voltages are beneficial for the battery storage system and DC-DC converter. While the cost of GaAs photovoltaics is significantly higher than for silicon, and is currently prohibitive for large area solar energy production, the small power requirements and associated size requirements for photovoltaic cells makes GaAs an affordable option. Requirements for active and standby power are 10μW and 0.5nW, respectively[1,2], where perpetual operation may be achieved using a photovoltaic cell with area on the order of 1 mm2.
  • Keywords
    DC-DC power convertors; III-V semiconductors; energy harvesting; gallium arsenide; photovoltaic cells; silicon; solar cells; DC-DC converter; GaAs; battery storage system; indoor lighting; indoor photovoltaic energy harvesting; photovoltaic cells; power 0.5 nW; power 10 muW; silicon CMOS; solar cells; wireless transceivers; Density measurement; Gallium arsenide; Lighting; Photovoltaic cells; Photovoltaic systems;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Device Research Conference (DRC), 2014 72nd Annual
  • Conference_Location
    Santa Barbara, CA
  • Print_ISBN
    978-1-4799-5405-6
  • Type

    conf

  • DOI
    10.1109/DRC.2014.6872392
  • Filename
    6872392