Wearable device designed by the Harvard A. Paulson School of Engineering
Now, researchers from the
Harvard John A. Paulson School of Engineering and Applied and Sciences (SEAS)
and the Wyss Institute for Biologically Inspired Engineering have developed an
efficient machine learning algorithm that can quickly tailor personalized
control strategies for soft, wearable exosuits.
The research is described
in Science Robotics.
"This new method is an
effective and fast way to optimize control parameter settings for assistive
wearable devices," said Ye Ding, a postdoctoral fellow at SEAS and
co-first author of the research. "Using this method, we achieved a huge
improvement in metabolic performance for the wearers of a hip extension
assistive device."
When humans walk, we
constantly tweak how we move to save energy (also known as metabolic cost).
"Before, if you had
three different users walking with assistive devices, you would need three
different assistance strategies," said Myunghee Kim, a postdoctoral
research fellow at SEAS and co-first author of the paper. "Finding the
right control parameters for each wearer used to be a difficult, step-by-step
process because not only do all humans walk a little differently but the
experiments required to manually tune parameters are complicated and
time-consuming"
The researchers, led by
Conor Walsh, the John L. Loeb Associate Professor of Engineering and Applied
Sciences, and Scott Kuindersma, Assistant Professor of Engineering and Computer
Science at SEAS, developed an algorithm that can cut through that variability
and rapidly identify the best control parameters that work best for minimizing
the of walking.
The researchers used
so-called human-in-the-loop optimization, which uses real-time measurements of
human physiological signals, such as breathing rate, to adjust the control
parameters of the device. As the algorithm honed in on the best parameters, it
directed the exosuit on when and where to deliver its assistive force to
improve hip extension. The Bayesian Optimization approach used by the team was
first reported in a paper last year in PLOSone.
The combination of the
algorithm and suit reduced metabolic cost by 17.4 percent compared to walking
without the device. This was a more than 60 percent improvement compared to the
team's previous work.
"Optimization and
learning algorithms will have a big impact on future wearable robotic devices
designed to assist a range of behaviors," said Kuindersma. "These
results show that optimizing even very simple controllers can provide a
significant, individualized benefit to users while walking. Extending these
ideas to consider more expressive control strategies and people with diverse
needs and abilities will be an exciting next step."
"With wearable robots
like soft exosuits, it is critical that the right assistance is delivered at
the right time so that they can work synergistically with the wearer,"
said Walsh. "With these online optimization algorithms, systems can learn
how do achieve this automatically in about twenty minutes, thus maximizing
benefit to the wearer."
Next, the team aims to
apply the optimization to a more complex device that assists multiple joints,
such as hip and ankle, at the same time.
"In this paper, we
demonstrated a high reduction in metabolic cost by just optimizing hip
extension," said Ding. "This goes to show what you can do with a
great brain and great hardware."
This research was supported
by the Defense Advanced Research Projects Agency, Warrior Web Program, the Wyss
Institute and the Harvard John A. Paulson School of Engineering and Applied
Science.
Story Source:
Materials provided
by Harvard John A. Paulson School of Engineering and Applied
Sciences. Original written by Leah
Burrows.
1 Comments
wow!!!!!!!!
ReplyDelete