Summary
Balance impairment affects a large proportion of the global population, as a symptom of many neurological diseases and a consequence of advanced age. Methods to improve balance through rehabilitation or assistive devices are effective but are limited by the availability of physiotherapists or by the strength and agility of the patient. While robotic assistive devices could augment mobility, extensive training is often necessary to receive the full benefits. BalancingACT will tackle this bottleneck by investigating methods to facilitate co-adaptation of user and balance assistance, providing personalized assistance directly targeting balance outcomes. The GyBAR, a gyroscopic backpack, has improved standing and walking balance for both healthy and stroke populations, but could benefit from targeted user training.
BalancingACT will address three main aspects of human-robot co-adaptation. I will first examine existing datasets from healthy and patient populations to determine which balance metrics explain differences between populations, providing a measure to gauge and optimize human-robot co-adaptation. I will then probe methods to improve motor learning for a healthy population in a challenging task, i.e., walking along a narrow beam. Exploration, driven by the individual or by the device, is a vital component of early learning. I will conduct two experiments, one to understand how self-guided exploration affects learning and one using human-in-the-loop optimization, a method to customize assistance by directly estimating the user’s response to a variety of candidate controllers, to determine the benefits of device-led exploration. This algorithm has previously elicited positive learning effects in exoskeletons and can also provide insight into the third aspect of co-adaptation: adapting the device to the user. In the long term, these results can be used to not only improve outcomes for the GyBAR but can also be generalized to other balance assistive devices.
BalancingACT will address three main aspects of human-robot co-adaptation. I will first examine existing datasets from healthy and patient populations to determine which balance metrics explain differences between populations, providing a measure to gauge and optimize human-robot co-adaptation. I will then probe methods to improve motor learning for a healthy population in a challenging task, i.e., walking along a narrow beam. Exploration, driven by the individual or by the device, is a vital component of early learning. I will conduct two experiments, one to understand how self-guided exploration affects learning and one using human-in-the-loop optimization, a method to customize assistance by directly estimating the user’s response to a variety of candidate controllers, to determine the benefits of device-led exploration. This algorithm has previously elicited positive learning effects in exoskeletons and can also provide insight into the third aspect of co-adaptation: adapting the device to the user. In the long term, these results can be used to not only improve outcomes for the GyBAR but can also be generalized to other balance assistive devices.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101106071 |
| Start date: | 01-08-2023 |
| End date: | 31-07-2025 |
| Total budget - Public funding: | - 187 624,00 Euro |
Cordis data
Original description
Balance impairment affects a large proportion of the global population, as a symptom of many neurological diseases and a consequence of advanced age. Methods to improve balance through rehabilitation or assistive devices are effective but are limited by the availability of physiotherapists or by the strength and agility of the patient. While robotic assistive devices could augment mobility, extensive training is often necessary to receive the full benefits. BalancingACT will tackle this bottleneck by investigating methods to facilitate co-adaptation of user and balance assistance, providing personalized assistance directly targeting balance outcomes. The GyBAR, a gyroscopic backpack, has improved standing and walking balance for both healthy and stroke populations, but could benefit from targeted user training.BalancingACT will address three main aspects of human-robot co-adaptation. I will first examine existing datasets from healthy and patient populations to determine which balance metrics explain differences between populations, providing a measure to gauge and optimize human-robot co-adaptation. I will then probe methods to improve motor learning for a healthy population in a challenging task, i.e., walking along a narrow beam. Exploration, driven by the individual or by the device, is a vital component of early learning. I will conduct two experiments, one to understand how self-guided exploration affects learning and one using human-in-the-loop optimization, a method to customize assistance by directly estimating the user’s response to a variety of candidate controllers, to determine the benefits of device-led exploration. This algorithm has previously elicited positive learning effects in exoskeletons and can also provide insight into the third aspect of co-adaptation: adapting the device to the user. In the long term, these results can be used to not only improve outcomes for the GyBAR but can also be generalized to other balance assistive devices.
Status
SIGNEDCall topic
HORIZON-MSCA-2022-PF-01-01Update Date
31-07-2023
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