Novel theorem demonstrates convolutional neural networks can always be trained on quantum computers, overcoming threat of ‘barren plateaus’ in optimization problems
From:
Department of Energy/Los Alamos National Laboratory
October 18, 2021 -- Convolutional neural
networks running on quantum computers have generated significant buzz for their
potential to analyze quantum data better than classical computers can. While a
fundamental solvability problem known as "barren plateaus" has
limited the application of these neural networks for large data sets, new
research overcomes that Achilles heel with a rigorous proof that guarantees
scalability.
"The way you construct a quantum
neural network can lead to a barren plateau -- or not," said Marco Cerezo,
coauthor of the paper titled "Absence of Barren Plateaus in Quantum
Convolutional Neural Networks," published today by a Los Alamos National
Laboratory team in Physical Review X. Cerezo is a physicist
specializing in quantum computing, quantum machine learning, and quantum
information at Los Alamos. "We proved the absence of barren plateaus for a
special type of quantum neural network. Our work provides trainability
guarantees for this architecture, meaning that one can generically train its
parameters."
As an artificial intelligence (AI)
methodology, quantum convolutional neural networks are inspired by the visual
cortex. As such, they involve a series of convolutional layers, or filters,
interleaved with pooling layers that reduce the dimension of the data while
keeping important features of a data set.
These neural networks can be used to
solve a range of problems, from image recognition to materials discovery.
Overcoming barren plateaus is key to extracting the full potential of quantum
computers in AI applications and demonstrating their superiority over classical
computers.
Until now, Cerezo said, researchers in
quantum machine learning analyzed how to mitigate the effects of barren
plateaus, but they lacked a theoretical basis for avoiding it altogether. The
Los Alamos work shows how some quantum neural networks are, in fact, immune to
barren plateaus.
"With this guarantee in hand,
researchers will now be able to sift through quantum-computer data about
quantum systems and use that information for studying material properties or
discovering new materials, among other applications," said Patrick Coles,
a quantum physicist at Los Alamos and a coauthor of the paper.
Many more applications for quantum AI
algorithms will emerge, Coles thinks, as researchers use near-term quantum
computers more frequently and generate more and more data -- all machine
learning programs are data-hungry.
Avoiding the Vanishing Gradient
"All hope of quantum speedup or
advantage is lost if you have a barren plateau," Cerezo said.
The crux of the problem is a
"vanishing gradient" in the optimization landscape. The landscape is
composed of hills and valleys, and the goal is to train the model's parameters
to find the solution by exploring the geography of the landscape. The solution
usually lies at the bottom of the lowest valley, so to speak. But in a flat
landscape one cannot train the parameters because it's difficult to determine
which direction to take.
That problem becomes particularly
relevant when the number of data features increases. In fact, the landscape
becomes exponentially flat with the feature size. Hence, in the presence of a
barren plateau, the quantum neural network cannot be scaled up.
The Los Alamos team developed a novel
graphical approach for analyzing the scaling within a quantum neural network
and proving its trainability.
For more than 40 years, physicists have
thought quantum computers would prove useful in simulating and understanding quantum
systems of particles, which choke conventional classical computers. The type of
quantum convolutional neural network that the Los Alamos research has proved
robust is expected to have useful applications in analyzing data from quantum
simulations.
"The field of quantum machine
learning is still young," Coles said. "There's a famous quote about
lasers, when they were first discovered, that said they were a solution in
search of a problem. Now lasers are used everywhere. Similarly, a number of us
suspect that quantum data will become highly available, and then quantum
machine learning will take off."
For instance, research is focusing on
ceramic materials as high-temperature superconductors, Coles said, which could
improve frictionless transportation, such as magnetic levitation trains. But
analyzing data about the material's large number of phases, which are
influenced by temperature, pressure, and impurities in these materials, and
classifying the phases is a huge task that goes beyond the capabilities of
classical computers.
Using a scalable quantum neural network,
a quantum computer could sift through a vast data set about the various states
of a given material and correlate those states with phases to identify the
optimal state for high-temperature superconducting.
https://www.sciencedaily.com/releases/2021/10/211018154236.htm
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