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Main Authors: Mitra, Kanishka, Racz, Frigyes Samuel, Kumar, Satyam, Deshpande, Ashish D., Millán, José del R.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.20885
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author Mitra, Kanishka
Racz, Frigyes Samuel
Kumar, Satyam
Deshpande, Ashish D.
Millán, José del R.
author_facet Mitra, Kanishka
Racz, Frigyes Samuel
Kumar, Satyam
Deshpande, Ashish D.
Millán, José del R.
contents Two distinct technologies have gained attention lately due to their prospects for motor rehabilitation: robotics and brain-machine interfaces (BMIs). Harnessing their combined efforts is a largely uncharted and promising direction that has immense clinical potential. However, a significant challenge is whether motor intentions from the user can be accurately detected using non-invasive BMIs in the presence of instrumental noise and passive movements induced by the rehabilitation exoskeleton. As an alternative to the straightforward continuous control approach, this study instead aims to characterize the onset and offset of motor imagery during passive arm movements induced by an upper-body exoskeleton to allow for the natural control (initiation and termination) of functional movements. Ten participants were recruited to perform kinesthetic motor imagery (MI) of the right arm while attached to the robot, simultaneously cued with LEDs indicating the initiation and termination of a goal-oriented reaching task. Using electroencephalogram signals, we built a decoder to detect the transition between i) rest and beginning MI and ii) maintaining and ending MI. Offline decoder evaluation achieved group average onset accuracy of 60.7% and 66.6% for offset accuracy, revealing that the start and stop of MI could be identified while attached to the robot. Furthermore, pseudo-online evaluation could replicate this performance, forecasting reliable online exoskeleton control in the future. Our approach showed that participants could produce quality and reliable sensorimotor rhythms regardless of noise or passive arm movements induced by wearing the exoskeleton, which opens new possibilities for BMI control of assistive devices.
format Preprint
id arxiv_https___arxiv_org_abs_2603_20885
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Characterizing the onset and offset of motor imagery during passive arm movements induced by an upper-body exoskeleton
Mitra, Kanishka
Racz, Frigyes Samuel
Kumar, Satyam
Deshpande, Ashish D.
Millán, José del R.
Robotics
Artificial Intelligence
Human-Computer Interaction
Two distinct technologies have gained attention lately due to their prospects for motor rehabilitation: robotics and brain-machine interfaces (BMIs). Harnessing their combined efforts is a largely uncharted and promising direction that has immense clinical potential. However, a significant challenge is whether motor intentions from the user can be accurately detected using non-invasive BMIs in the presence of instrumental noise and passive movements induced by the rehabilitation exoskeleton. As an alternative to the straightforward continuous control approach, this study instead aims to characterize the onset and offset of motor imagery during passive arm movements induced by an upper-body exoskeleton to allow for the natural control (initiation and termination) of functional movements. Ten participants were recruited to perform kinesthetic motor imagery (MI) of the right arm while attached to the robot, simultaneously cued with LEDs indicating the initiation and termination of a goal-oriented reaching task. Using electroencephalogram signals, we built a decoder to detect the transition between i) rest and beginning MI and ii) maintaining and ending MI. Offline decoder evaluation achieved group average onset accuracy of 60.7% and 66.6% for offset accuracy, revealing that the start and stop of MI could be identified while attached to the robot. Furthermore, pseudo-online evaluation could replicate this performance, forecasting reliable online exoskeleton control in the future. Our approach showed that participants could produce quality and reliable sensorimotor rhythms regardless of noise or passive arm movements induced by wearing the exoskeleton, which opens new possibilities for BMI control of assistive devices.
title Characterizing the onset and offset of motor imagery during passive arm movements induced by an upper-body exoskeleton
topic Robotics
Artificial Intelligence
Human-Computer Interaction
url https://arxiv.org/abs/2603.20885