When the human brain learns something new, it adapts. But when artificial intelligence learns something new, it tends to forget information it already learned.
From:
Perdue University
February
3, 2022 -- As companies use more and more data to improve how AI recognizes
images, learns languages and carries out other complex tasks, a paper
publishing in Science this week shows a way that computer chips could
dynamically rewire themselves to take in new data like the brain does, helping
AI to keep learning over time.
"The brains of living beings can
continuously learn throughout their lifespan. We have now created an artificial
platform for machines to learn throughout their lifespan," said Shriram
Ramanathan, a professor in Purdue University's School of Materials Engineering
who specializes in discovering how materials could mimic the brain to improve
computing.
Unlike the brain, which constantly forms
new connections between neurons to enable learning, the circuits on a computer
chip don't change. A circuit that a machine has been using for years isn't any
different than the circuit that was originally built for the machine in a
factory.
This is a problem for making AI more
portable, such as for autonomous vehicles or robots in space that would have to
make decisions on their own in isolated environments. If AI could be embedded
directly into hardware rather than just running on software as AI typically
does, these machines would be able to operate more efficiently.
In this study, Ramanathan and his team
built a new piece of hardware that can be reprogrammed on demand through
electrical pulses. Ramanathan believes that this adaptability would allow the
device to take on all of the functions that are necessary to build a
brain-inspired computer.
"If we want to build a computer or
a machine that is inspired by the brain, then correspondingly, we want to have
the ability to continuously program, reprogram and change the chip,"
Ramanathan said.
Toward building a brain in chip form
The hardware is a small, rectangular
device made of a material called perovskite nickelate, which is very sensitive
to hydrogen. Applying electrical pulses at different voltages allows the device
to shuffle a concentration of hydrogen ions in a matter of nanoseconds,
creating states that the researchers found could be mapped out to corresponding
functions in the brain.
When the device has more hydrogen near
its center, for example, it can act as a neuron, a single nerve cell. With less
hydrogen at that location, the device serves as a synapse, a connection between
neurons, which is what the brain uses to store memory in complex neural
circuits.
Through simulations of the experimental
data, the Purdue team's collaborators at Santa Clara University and Portland
State University showed that the internal physics of this device creates a
dynamic structure for an artificial neural network that is able to more
efficiently recognize electrocardiogram patterns and digits compared to static
networks. This neural network uses "reservoir computing," which
explains how different parts of a brain communicate and transfer information.
Researchers from The Pennsylvania State
University also demonstrated in this study that as new problems are presented,
a dynamic network can "pick and choose" which circuits are the best
fit for addressing those problems.
Since the team was able to build the
device using standard semiconductor-compatible fabrication techniques and
operate the device at room temperature, Ramanathan believes that this technique
can be readily adopted by the semiconductor industry.
"We demonstrated that this device
is very robust," said Michael Park, a Purdue Ph.D. student in materials
engineering. "After programming the device over a million cycles, the
reconfiguration of all functions is remarkably reproducible."
The researchers are working to
demonstrate these concepts on large-scale test chips that would be used to
build a brain-inspired computer.
Experiments at Purdue were conducted at
the FLEX Lab and Birck Nanotechnology Center of Purdue's Discovery Park. The
team's collaborators at Argonne National Laboratory, the University of
Illinois, Brookhaven National Laboratory and the University of Georgia
conducted measurements of the device's properties.
The research was supported by the U.S.
Department of Energy Office of Science, the Air Force Office of Scientific
Research and the National Science Foundation.
https://www.sciencedaily.com/releases/2022/02/220203160544.htm
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