TY - JOUR
T1 - The Future of Bionic Limbs: The untapped synergy of signal processing, control, and wireless connectivity
AU - Chiariotti, Federico
AU - Mamidanna, Pranav
AU - Suman, Suraj
AU - Stefanović, Čedomir
AU - Farina, Dario
AU - Popovski, Petar
AU - Došen, Strahinja
PY - 2024
Y1 - 2024
N2 - The flexibility and dexterity of human limbs rely on the processing of a vast quantity of signals within the sensory-motor networks in the brain and spinal cord, distilled into stimuli that govern the commands and movements. Hence, the use of assistive devices, such as robotic limbs or exoskeletons, is critically dependent on the processing of a large number of heterogeneous signals to mimic natural movements. This article provides a panoramic overview of the three paradigms for the control of bionic limbs based on mechatronic technology. Two of them have already been established in the literature, while the third one, advocated by this article, is an emerging approach, enabled by the latest developments in connectivity and computation. In the first paradigm, the bionic limbs rely on conventional control and are directly reconnected to the human sensory-motor system, which requires a large signal processing bandwidth. The second paradigm is based on semiautonomous limbs, endowed with context-aware processing and certain decision capability. Following the advances in wireless connectivity and cloud/edge processing, this article introduces a third paradigm of connected limbs.
AB - The flexibility and dexterity of human limbs rely on the processing of a vast quantity of signals within the sensory-motor networks in the brain and spinal cord, distilled into stimuli that govern the commands and movements. Hence, the use of assistive devices, such as robotic limbs or exoskeletons, is critically dependent on the processing of a large number of heterogeneous signals to mimic natural movements. This article provides a panoramic overview of the three paradigms for the control of bionic limbs based on mechatronic technology. Two of them have already been established in the literature, while the third one, advocated by this article, is an emerging approach, enabled by the latest developments in connectivity and computation. In the first paradigm, the bionic limbs rely on conventional control and are directly reconnected to the human sensory-motor system, which requires a large signal processing bandwidth. The second paradigm is based on semiautonomous limbs, endowed with context-aware processing and certain decision capability. Following the advances in wireless connectivity and cloud/edge processing, this article introduces a third paradigm of connected limbs.
KW - Wireless communication
KW - Wireless sensor networks
KW - Spinal cord
KW - Mechatronics
KW - Exoskeletons
KW - Bandwidth
KW - Signal processing
KW - Robot sensing systems
KW - Assistive devices
UR - http://www.scopus.com/inward/record.url?scp=85206879678&partnerID=8YFLogxK
U2 - 10.1109/MSP.2024.3401403
DO - 10.1109/MSP.2024.3401403
M3 - Journal article
SN - 1053-5888
VL - 41
SP - 58
EP - 75
JO - IEEE Signal Processing Magazine
JF - IEEE Signal Processing Magazine
IS - 4
ER -