TY - JOUR
T1 - Dual-Parameter Modulation Improves Stimulus Localization in Multichannel Electrotactile Stimulation
AU - Seminara, Lucia
AU - Fares, Hoda
AU - Franceschi, Marta
AU - Valle, Maurizio
AU - Strbac, Matija
AU - Farina, Dario
AU - Dosen, Strahinja
N1 - Publisher Copyright:
© 2008-2011 IEEE.
PY - 2020/4/1
Y1 - 2020/4/1
N2 - Among most challenging open issues in prosthetic research is the development of a robust bidirectional interface between a prosthesis and its user. Commercially available prosthetic systems are mechanically advanced, but they do not provide somatosensory feedback. Here, we present a novel non-invasive interface for multichannel electrotactile feedback, comprising a matrix of 24 pads, and we investigate the ability of able-bodied human subjects to localize the electrotactile stimulus delivered through the matrix. For this purpose, we tested conventional stimulation (same frequency for all pads) and a novel dual-parameter modulation scheme (interleaved frequency and intensity) designed to facilitate the spatial localization over the electrode. Electrotactile stimulation was also compared to mechanical stimulation of the same locations on the skin. Experimental results on eight able-bodied subjects demonstrated that the proposed interleaved coding substantially improved the spatial localization compared to same-frequency stimulation. The results also showed that same-frequency stimulation was equivalent to mechanical stimulation, whereas the performance with dual-parameter modulation was significantly better. These are encouraging outcomes for the application of a multichannel interface for the restoration of feedback in prosthetics. The high-resolution augmented interfaces might be used to explore novel scenarios for effective communication with the prosthesis user enabled by maximizing information transmission.
AB - Among most challenging open issues in prosthetic research is the development of a robust bidirectional interface between a prosthesis and its user. Commercially available prosthetic systems are mechanically advanced, but they do not provide somatosensory feedback. Here, we present a novel non-invasive interface for multichannel electrotactile feedback, comprising a matrix of 24 pads, and we investigate the ability of able-bodied human subjects to localize the electrotactile stimulus delivered through the matrix. For this purpose, we tested conventional stimulation (same frequency for all pads) and a novel dual-parameter modulation scheme (interleaved frequency and intensity) designed to facilitate the spatial localization over the electrode. Electrotactile stimulation was also compared to mechanical stimulation of the same locations on the skin. Experimental results on eight able-bodied subjects demonstrated that the proposed interleaved coding substantially improved the spatial localization compared to same-frequency stimulation. The results also showed that same-frequency stimulation was equivalent to mechanical stimulation, whereas the performance with dual-parameter modulation was significantly better. These are encouraging outcomes for the application of a multichannel interface for the restoration of feedback in prosthetics. The high-resolution augmented interfaces might be used to explore novel scenarios for effective communication with the prosthesis user enabled by maximizing information transmission.
KW - Electrotactile stimulation
KW - matrix electrodes
KW - mechanical stimulation
KW - sensory feedback
KW - spatial localization
UR - http://www.scopus.com/inward/record.url?scp=85074534380&partnerID=8YFLogxK
U2 - 10.1109/TOH.2019.2950625
DO - 10.1109/TOH.2019.2950625
M3 - Article
C2 - 31675343
AN - SCOPUS:85074534380
SN - 1939-1412
VL - 13
SP - 393
EP - 403
JO - IEEE Transactions on Haptics
JF - IEEE Transactions on Haptics
IS - 2
M1 - 8888238
ER -