TY - JOUR
T1 - Novel Electrode Designs for Electrotactile Stimulation of the Finger
T2 - A Comparative Assessment
AU - Garenfeld, Martin A.
AU - Henrich, Mauricio Carlos
AU - Isaković, Milica
AU - Malešević, Jovana
AU - Štrbac, Matija
AU - Došen, Strahinja
PY - 2023/10
Y1 - 2023/10
N2 - Electrotactile stimulation can be an attractive technology to restore tactile feedback in different application scenarios (e.g., virtual and augmented reality, tele-manipulation). This technology allows designing compact solutions with no mechanical elements that can integrate a high-density matrix of stimulation points. The present study introduced four novel multi-pad finger-electrode designs with different arrangements (two matrix and two circular) and shapes of active pads (producing sensation) and reference pads (ideally, no sensation produced below the pad). The electrodes were used to investigate the subjects' ability to spatially discriminate active pads within phalanges individually (6-9 pads) as well as across the full finger (18-19 pads). The tests were conducted in 12 subjects and the results showed that all designs led to high success rates when applied to the fingertip (70-81%). When tested on the full finger, the matrix and circular designs were characterized with similar performance (54-57%), and when the phalanges were analyzed individually, the spatial discrimination was best at the fingertip. Additionally, new approaches for faster amplitude calibration were proposed and tested, demonstrating that calibration duration can be reduced by approximately 40% compared to the standard approach of calibrating single pads individually. Finally, discrimination tests of dynamic tactile patterns were conducted using circular and matrix designs on the fingertip and full finger, respectively. The tests showed that the different patterns generated by the two arrangements could be clearly discriminated, especially in the case of full-finger matrix-style patterns. The present study, therefore, provides several important insights that are relevant when delivering tactile feedback to the finger using an electrotactile interface.
AB - Electrotactile stimulation can be an attractive technology to restore tactile feedback in different application scenarios (e.g., virtual and augmented reality, tele-manipulation). This technology allows designing compact solutions with no mechanical elements that can integrate a high-density matrix of stimulation points. The present study introduced four novel multi-pad finger-electrode designs with different arrangements (two matrix and two circular) and shapes of active pads (producing sensation) and reference pads (ideally, no sensation produced below the pad). The electrodes were used to investigate the subjects' ability to spatially discriminate active pads within phalanges individually (6-9 pads) as well as across the full finger (18-19 pads). The tests were conducted in 12 subjects and the results showed that all designs led to high success rates when applied to the fingertip (70-81%). When tested on the full finger, the matrix and circular designs were characterized with similar performance (54-57%), and when the phalanges were analyzed individually, the spatial discrimination was best at the fingertip. Additionally, new approaches for faster amplitude calibration were proposed and tested, demonstrating that calibration duration can be reduced by approximately 40% compared to the standard approach of calibrating single pads individually. Finally, discrimination tests of dynamic tactile patterns were conducted using circular and matrix designs on the fingertip and full finger, respectively. The tests showed that the different patterns generated by the two arrangements could be clearly discriminated, especially in the case of full-finger matrix-style patterns. The present study, therefore, provides several important insights that are relevant when delivering tactile feedback to the finger using an electrotactile interface.
KW - Electrodes
KW - Fingers
KW - Haptic interfaces
KW - Piezoelectric transducers
KW - Shape
KW - Skin
KW - Tactile sensors
KW - virtual reality
KW - spatial discrimination
KW - electrode design
KW - Electrotactile stimulation
KW - tactile feedback
KW - haptic effects
KW - touch sensations
UR - http://www.scopus.com/inward/record.url?scp=85174839751&partnerID=8YFLogxK
U2 - 10.1109/TOH.2023.3321925
DO - 10.1109/TOH.2023.3321925
M3 - Journal article
SN - 2334-0134
VL - 16
SP - 748
EP - 759
JO - IEEE Transactions on Haptics
JF - IEEE Transactions on Haptics
IS - 4
M1 - 10273438
ER -