Fur interface with bristling effect induced by vibration

Wearable computing technology is one of the methods that can augment the information processing ability of humans. However, in this area, a soft surface is often necessary to maximize the comfort and practicality of such wearable devices. Thus in this paper, we propose a soft surface material, with an organic bristling effect achieved through mechanical vibration, as a new user interface. We have used fur in order to exhibit the visually rich transformation induced by the bristling effect while also achieving the full tactile experience and benefits of soft materials. Our method needs only a layer of fur and simple vibration motors. The hairs of fur instantly bristle with only horizontal mechanical vibration. The vibration is provided by a simple vibration motor embedded below the fur material. This technology has significant potential as garment textiles or to be utilized as a general soft user interface.

[1]  Katashi Nagao,et al.  The world through the computer: computer augmented interaction with real world environments , 1995, UIST '95.

[2]  Robert W. Lindeman,et al.  Wearable vibrotactile systems for virtual contact and information display , 2006, Virtual Reality.

[3]  Pattie Maes,et al.  Shutters: a permeable surface for environmental control and communication , 2009, TEI.

[4]  Steve Yohanan,et al.  The Haptic Creature : social human-robot interaction through affective touch , 2012 .

[5]  Hiroyuki Kajimoto,et al.  Emotional touch: a novel interface to display "emotional" tactile information to a palm , 2008, SIGGRAPH '08.

[6]  Takanori Shibata,et al.  Psychological and Social Effects of One Year Robot Assisted Activity on Elderly People at a Health Service Facility for the Aged , 2005, Proceedings of the 2005 IEEE International Conference on Robotics and Automation.

[7]  1995 Liu,et al.  United States Patent , 2011 .

[8]  K. MacLean,et al.  The Haptic Creature Project : Social Human-Robot Interaction through Affective Touch , 2008 .

[9]  J.-Y. Bouguet,et al.  Pyramidal implementation of the lucas kanade feature tracker , 1999 .

[10]  Emily B. Cooper,et al.  Fabric computing interfaces , 1998, CHI Conference Summary.

[11]  Steve Mann,et al.  Wearable Computing: A First Step Toward Personal Imaging , 1997, Computer.

[12]  Enzo Pasquale Scilingo,et al.  ELECTROACTIVE FABRICS AND WEARABLE BIOMONITORING DEVICES , 2003, AUTEX Research Journal.

[13]  J. Brown Behavioral Ecology and Sociobiology , 2019, Encyclopedia of Animal Behavior.

[14]  Michitaka Hirose,et al.  Virtual leading blocks for the deaf-blind: a real-time way-finder by verbal-nonverbal hybrid interface and high-density RFID tag space , 2004, IEEE Virtual Reality 2004.

[15]  Lucy E. Dunne,et al.  A shoulder pad insert vibrotactile display , 2003, Seventh IEEE International Symposium on Wearable Computers, 2003. Proceedings..

[16]  Roshan Lalintha Peiris,et al.  Huggy Pajama: a mobile parent and child hugging communication system , 2008, IDC.

[17]  Pattie Maes,et al.  Sprout I/O: a texturally rich interface , 2008, TEI.

[18]  Carol Porth,et al.  Essentials of Pathophysiology: Concepts of Altered Health States , 2003 .

[19]  Akira Wakita,et al.  Mosaic textile: wearable ambient display with non-emissive color-changing modules , 2006, ACE '06.

[20]  James Tichenor,et al.  Super cilia skin: an interactive membrane , 2003, CHI Extended Abstracts.

[21]  Masa Inakage,et al.  Tabby: designing of coexisting entertainment content in everyday life by expanding the design of furniture , 2007, ACE '07.

[22]  Hiroshi Ishii,et al.  Tangible bits: towards seamless interfaces between people, bits and atoms , 1997, CHI.

[23]  F. Waal,et al.  Reconciliation and consolation among chimpanzees , 1979, Behavioral Ecology and Sociobiology.