Task-Dependent Adaptations in Closed-Loop Motor Control Based on Electrotactile Feedback

Abstract: Humans systematically adapt their strategies for closed-loop control based on visual feedback according to the dynamics of the system. Tactile feedback is a key element in many human-machine interfaces, but it is not known if and how well human control adapts to changes in system dynamics when information about the system state is provided using this type of feedback. In this study, 11 participants tracked a pseudorandom trajectory with a virtual, position-or velocity-controlled plant using a joystick. Visual … Show more

“…2) Target trajectory: The target trajectory was a pseudorandom signal formed by the sum of nine sine waves with logarithmically spaced frequencies between 0.2 and 6.3 rad/s [33]. This type of reference trajectory is often used for the assessment of human manual control in tracking paradigms (e.g., see [14], [34]). The amplitudes of the five sine waves with the lowest frequencies (≤ 1 rad/s) were set to be twice as high as the amplitude of the other four sine waves to decrease the task difficulty while maintaining the desired bandwidth.…”

Closed-loop Manual Control with Tactile or Visual Feedback under Wireless Link Impairments

“…2) Target trajectory: The target trajectory was a pseudorandom signal formed by the sum of nine sine waves with logarithmically spaced frequencies between 0.2 and 6.3 rad/s [33]. This type of reference trajectory is often used for the assessment of human manual control in tracking paradigms (e.g., see [14], [34]). The amplitudes of the five sine waves with the lowest frequencies (≤ 1 rad/s) were set to be twice as high as the amplitude of the other four sine waves to decrease the task difficulty while maintaining the desired bandwidth.…”

Closed-loop Manual Control with Tactile or Visual Feedback under Wireless Link Impairments

“…Sensory substitution via electrotactile or mechanotactile stimulation is widely studied to provide sensory information indirectly. Electrotactile substitute feedback has been applied to restore the perception of various physical features [112][113][114] or precise grasp control [115][116][117][118]. The amplitude, frequency, and pulse width of electrotactile stimulation can be modulated independently to encode a range of sensory information.…”

Biorealistic hand prosthesis with compliance control and noninvasive somatotopic sensory feedback

“…Electro-tactile stimulation (ECS), for example, works by injecting small electrical currents across the skin, thereby not affecting muscle contractions, and maintaining compatibility with sensing techniques for intent detection (e.g., sEMG, see Došen et al, 2017). Highdensity integrated ECS delivers highly differentiated stimuli, both qualitatively and quantitatively, at essentially no additional psychological burden for the user (Dideriksen et al, 2022;Isaković et al, 2022). In my opinion, any advantage delivered by direct connection to the afferent nerves, e.g., cuff or intrafascicular electrodes [and there is ample evidence for their effectiveness, see for instance (D'Anna et al, 2019;Petrini et al, 2019)], needs to face an inevitable acceptance gap; moreover, here, too, as it was the case for ID, the technologies involved in ECS vs. invasive techniques belong to two different levels of maturity.…”

Peripheral Nervous System Interfaces: Invasive or Non-invasive?