• DocumentCode
    2791935
  • Title

    The effect of fingertip microstructures on tactile edge perception

  • Author

    Gerling, Gregory J. ; Thomas, Geb W.

  • Author_Institution
    Dept. of Mech. & Ind. Eng., Iowa Univ., Iowa City, IA, USA
  • fYear
    2005
  • fDate
    18-20 March 2005
  • Firstpage
    63
  • Lastpage
    72
  • Abstract
    People rely on tactile edge localization to ascertain the location and structure of edges. When pressure is applied to the skin, skin mechanoreceptors convert compressive stress/strain into neural signals. Many attempts to model this conversion neglect intermediate ridges, on the inside of the stiff epidermis. The receptors associated with detecting compressive and shear stresses reside at the tips of these ridges, suggesting a functional importance in the detection of stress. This work considers how underlying microstructure affects the mechanical propagation of stress to receptors. Two unique indenters are applied to two finite element models of idealized, fingerpad skin - one with ridge microstructure. Findings indicate that microstructure produces high, local stress concentrations at ridge tips near receptors. Because stress is focused at ridges beneath edges, there is a higher contrast of stress between ridge tips near the indenter´s edge and those adjacent. This lensing effect mechanism appears to help distinguish edges.
  • Keywords
    edge detection; finite element analysis; haptic interfaces; human computer interaction; neurophysiology; skin; stress analysis; touch (physiological); fingerpad skin; fingertip microstructures; finite element models; shear stress; skin mechanoreceptors; tactile edge perception; Capacitive sensors; Compressive stress; Epidermis; Finite element methods; Image edge detection; Industrial engineering; Microstructure; Skin; Surface morphology; Vibrations;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Eurohaptics Conference, 2005 and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, 2005. World Haptics 2005. First Joint
  • Print_ISBN
    0-7695-2310-2
  • Type

    conf

  • DOI
    10.1109/WHC.2005.129
  • Filename
    1406915