• DocumentCode
    972604
  • Title

    Integrated Circuitry to Detect Slippage Inspired by Human Skin and Artificial Retinas

  • Author

    Maldónado-López, Rocío ; Vidal-Verdú, Fernando ; Liñán, Gustavo ; Rodríguez-Vázquez, Ángel

  • Author_Institution
    IMSE, Seville, Spain
  • Volume
    56
  • Issue
    8
  • fYear
    2009
  • Firstpage
    1554
  • Lastpage
    1565
  • Abstract
    This paper presents a bioinspired integrated tactile coprocessor that is able to generate a warning in the case of slippage via the data provided by a tactile sensor. Some implementations use different layers of piezoresistive and piezoelectric materials to build upon the raw sensor and obtain the static (pressure) as well as the dynamic (slippage) information. In this paper, a simple raw sensor is used, and a circuitry is implemented, which is able to extract the dynamic information from a single piezoresistive layer. The circuitry was inspired by structures found in human skin and retina, as they are biological systems made up of a dense network of receptors. It is largely based on an artificial retina , which is able to detect motion by using relatively simple spatial temporal dynamics. The circuitry was adapted to respond in the bandwidth of microvibrations produced by early slippage, resembling human skin. Experimental measurements from a chip implemented in a 0.35-mum four-metal two-poly standard CMOS process are presented to show both the performance of the building blocks included in each processing node and the operation of the whole system as a detector of early slippage.
  • Keywords
    CMOS integrated circuits; application specific integrated circuits; bio-inspired materials; coprocessors; elemental semiconductors; microsensors; piezoelectric devices; piezoresistive devices; silicon; spatiotemporal phenomena; tactile sensors; vibrations; ASIC; MEMS; Si; application-specific integrated circuit; artificial retina inspired sensor; bioinspired integrated tactile coprocessor; dynamic slippage; four-metal two-polystandard CMOS process; human skin inspired tactile sensor; integrated circuitry; microvibrations; piezoelectric materials; piezoresistive layer; raw sensor; silicon retinas; slippage detection; spatial temporal dynamics; static slippage; Bioinspired chips; slippage detection; tactile sensors;
  • fLanguage
    English
  • Journal_Title
    Circuits and Systems I: Regular Papers, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1549-8328
  • Type

    jour

  • DOI
    10.1109/TCSI.2008.2008290
  • Filename
    4663665