Machine Learning Algorithm
Predicts How to Get the Most out of Electric Vehicle Batteries
Researchers
have developed a machine learning algorithm that could help reduce charging
times and prolong battery life in electric vehicles by predicting how different
driving patterns affect battery performance, improving safety and reliability.
From: University of Cambridge
August 23, 2022 -- The
researchers, from the University of Cambridge, say their algorithm could help
drivers, manufacturers and businesses get the most out of the batteries that
power electric vehicles by suggesting routes and driving patterns which
minimise battery degradation and charging times.
The team developed a
non-invasive way to probe batteries and get a holistic view of battery health.
These results were then fed into a machine learning algorithm that can predict
how different driving patterns will affect the future health of the battery.
If developed
commercially, the algorithm could be used to recommend routes which get drivers
from point to point in the shortest time without degrading the battery, for
example, or recommend the fastest way to charge the battery without causing it
to degrade. The results are reported in the journal Nature
Communications.
The health of a
battery, whether it's in a smartphone or a car, is far more complex than a
single number on a screen. "Battery health, like human health, is a
multi-dimensional thing, and it can degrade in lots of different ways,"
said first author Penelope Jones, from Cambridge's Cavendish Laboratory.
"Most methods of monitoring battery health assume that a battery is always
used in the same way. But that's not how we use batteries in real life. If I'm
streaming a TV show on my phone, it's going to run down the battery a whole lot
faster than if I'm using it for messaging. It's the same with electric cars --
how you drive will affect how the battery degrades."
"Most of us will
replace our phones well before the battery degrades to the point that it's
unusable, but for cars, the batteries need to last for five, ten years or
more," said Dr Alpha Lee, who led the research. "Battery capacity can
change drastically over that time, so we wanted to come up with a better way of
checking battery health."
The researchers
developed a non-invasive probe which sends high dimensional electrical pulses
into a battery and measures the response, providing a series of 'biomarkers' of
battery health. This method is gentle on the battery and doesn't cause it to
degrade any further.
The electrical signals
from the battery were converted into a description of the battery's state,
which was fed into a machine learning algorithm. The algorithm was able to
predict how the battery would respond in the next charge-discharge cycle,
depending on how quickly the battery was charged and how fast the car would be
going the next time it was on the road. Tests with 88 commercial batteries
showed that the algorithm did not require any information about previous usage
of the battery to make an accurate prediction.
The experiment focused
on lithium cobalt oxide (LCO) cells, which are widely used in rechargeable
batteries, but the method is generalisable across the different types of
battery chemistries used in electric vehicles today.
"This method could
unlock value in so many parts of the supply chain, whether you're a
manufacturer, an end user, or a recycler, because it allows to capture the
health of the battery beyond a single number, and because it's
predictive," said Lee. "It could reduce the time it takes to develop
new type of batteries, because we'll be able to predict how they will degrade
under different operating conditions."
The researchers say
that in addition to manufacturers and drivers, their method could be useful for
businesses which operate large fleets of electric vehicles, such as logistics
companies. "The framework we've developed could help companies optimise how
they use their vehicles to improve the overall battery life of the fleet,"
said Lee. "There's so much potential with a framework like this."
"It's been such an
exciting framework to build, because it could solve so many of the challenges
in the battery field today," said Jones. "It's a great time to be
involved in the field of battery research, which is so important in helping
address climate change by transitioning away from fossil fuels."
The researchers are now
working with battery manufacturers to accelerate the development of safer,
longer lasting next-generation batteries. They are also exploring how their
framework could be used to develop optimal fast charging protocols to reduce
electric vehicle charging times without causing degradation.
The research was
supported by the Winton Programme for the Physics of Sustainability, the Ernest
Oppenheimer Fund, the Alan Turing Institute and the Royal Society.
https://www.sciencedaily.com/releases/2022/08/220823162725.htm
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