Table of Contents

Haptics

see also the Haptic Feedback topic

Terramachine:

Feelex

feelex1.jpg

Biorobotics and Biomimetics

A Large Interactive Tactile Interface Project (CORDIS)

Super cilia skin

banner.jpg

GelForce

Biomotors

Pins

Aegis Hyposurface (decoi)

FE_2003_Hyposurface_002_m.jpg

Using pneumatic pistons and springs: http://www.sial.rmit.edu.au/Projects/Aegis_Hyposurface.php

“Behind the façade’s surface, many pneumatic pistons attach to metal plates that form the wall surface. Springs are then attached to both the pistons and the static structural frame, helping to control the location of each piston by providing it with a failsafe means of returning to a known starting point or resting state. By understanding the typical way pneumatic pistons are controlled we can also understand how the wall is actuated by distributing air pressure between two different pneumatic chambers (within the body of a piston) in different combinations to allow the piston to extend, to contract, or alternatively jitter in a mode that enables it to extend and contract very rapidly. A computer was then programmed to fire each piston sequentially in order to produce a series of patterns that responded to environmental stimuli—sound being the particular stimuli used.” Sterk, Tristan d’Estrée

Other Refs

Electroactive polymer research

Also see the Active Materials topic

Electronic whiteboards

These are based either on near-field ultrasound tracking, as in mimio http://www.mimio.com , or on extremely skewed video acquisition. I had in mind the latter, thinking that it might be possible to use video acquisition, with the touchable surface, say, separated from a coated translucent hard sheet of acrylic or something, so that pressure upon the material causes certain regions of the sheep to appear darker (or lighter) than others. Or, in any case, arranging things such that a pattern of light and dark is what would result from pressure upon the surface.