Can intelligence be taught to robots? Advances in physical reservoir computing, a technology that makes sense of brain signals, could contribute to creating artificial intelligence machines that think as we do.
From:
American Institute of Physics
October 26, 2021 -- Researchers outline
how a robot could be taught to navigate through a maze by electrically
stimulating a culture of brain nerve cells connected to the machine. These
nerve cells were grown from living cells and acted as the physical reservoir
for the computer to construct coherent signals. These findings suggest
goal-directed behavior can be generated without any additional learning by
sending disturbance signals to an embodied system.
In Applied Physics Letters,
from AIP Publishing, researchers from the University of Tokyo outline how a
robot could be taught to navigate through a maze by electrically stimulating a
culture of brain nerve cells connected to the machine.
These nerve cells, or neurons, were
grown from living cells and acted as the physical reservoir for the computer to
construct coherent signals.
The signals are regarded as homeostatic
signals, telling the robot the internal environment was being maintained within
a certain range and acting as a baseline as it moved freely through the maze.
Whenever the robot veered in the wrong
direction or faced the wrong way, the neurons in the cell culture were
disturbed by an electric impulse. Throughout trials, the robot was continually
fed the homeostatic signals interrupted by the disturbance signals until it had
successfully solved the maze task.
These findings suggest goal-directed
behavior can be generated without any additional learning by sending
disturbance signals to an embodied system. The robot could not see the
environment or obtain other sensory information, so it was entirely dependent on
the electrical trial-and-error impulses.
"I, myself, was inspired by our
experiments to hypothesize that intelligence in a living system emerges from a
mechanism extracting a coherent output from a disorganized state, or a chaotic
state," said co-author Hirokazu Takahashi, an associate professor of
mechano-informatics.
Using this principle, the researchers
show intelligent task-solving abilities can be produced using physical
reservoir computers to extract chaotic neuronal signals and deliver homeostatic
or disturbance signals. In doing so, the computer creates a reservoir that
understands how to solve the task.
"A brain of [an] elementary school
kid is unable to solve mathematical problems in a college admission exam,
possibly because the dynamics of the brain or their 'physical reservoir
computer' is not rich enough," said Takahashi. "Task-solving ability
is determined by how rich a repertoire of spatiotemporal patterns the network
can generate."
The team believes using physical
reservoir computing in this context will contribute to a better understanding
of the brain's mechanisms and may lead to the novel development of a
neuromorphic computer.
https://www.sciencedaily.com/releases/2021/10/211026124247.htm
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