Artificial Neuron Device Could Shrink Energy Use and Size of Neural Network Hardware

Training neural networks to perform tasks, such as recognizing images or navigating self-driving cars, could one day require less computing power and hardware thanks to a new artificial neuron device developed by researchers at the University of California San Diego. The device can run neural network computations using 100 to 1000 times less energy and area than existing CMOS-based hardware.

Researchers report their work in a paper published Mar. 18 in Nature Nanotechnology.

SEM image of the artificial neuron device

 Images courtesy of Nature Nanotechnology

Neural networks are a series of connected layers of artificial neurons, where the output of one layer provides the input to the next. Generating that input is done by applying a mathematical calculation called a non-linear activation function. This is a critical part of running a neural network. But applying this function requires a lot of computing power and circuitry because it involves transferring data back and forth between two separate units—the memory and an external processor.

Now, UC San Diego researchers have developed a nanometer-sized device that can efficiently carry out the activation function.

“Neural network computations in hardware get increasingly inefficient as the neural network models get larger and more complex,” said corresponding author Duygu Kuzum, a professor of electrical and computer engineering at the UC San Diego Jacobs School of Engineering. “We developed a single nanoscale artificial neuron device that implements these computations in hardware in a very area- and energy-efficient way.”

The new study was performed as a collaboration between UC San Diego researchers from the Department of Electrical and Computer Engineering (led by Kuzum, who is part of the university’s Center for Machine-Integrated Computing and Security) and a DOE Energy Frontier Research Center (EFRC led by physics professor Ivan Schuller), which focuses on developing hardware implementations of energy-efficient artificial neural networks.

The device implements one of the most commonly used activation functions in neural network training called a rectified linear unit. What’s particular about this function is that it needs hardware that can undergo a gradual change in resistance in order to work. And that’s exactly what the UC San Diego researchers engineered their device to do—it can gradually switch from an insulating to a conducting state, and it does so with the help of a little bit of heat.

This switch is what’s called a Mott transition. It takes place in a nanometers-thin layer of vanadium dioxide. Above this layer is a nanowire heater made of titanium and gold. When current flows through the nanowire, the vanadium dioxide layer slowly heats up, causing a slow, controlled switch from insulating to conducting.

“This device architecture is very interesting and innovative,” said first author Sangheon Oh, an electrical and computer engineering Ph.D. student in Kuzum’s lab. Typically, materials in a Mott transition experience an abrupt switch from insulating to conducting because the current flows directly through the material, he explained. “In this case, we flow current through a nanowire on top of the material to heat it and induce a very gradual resistance change.”