While today's AI chips are electronic and rely on electricity to perform calculations, the new chip is photonic, meaning it uses beams of light instead. Described in Nature Photonics, the chip reshapes how light behaves to carry out the nonlinear mathematics at the heart of modern AI.
"Nonlinear functions are critical for training deep neural networks," says Liang Feng, Professor in Materials Science and Engineering (MSE) and in Electrical and Systems Engineering (ESE), and the paper's senior author. "Our aim was to make this happen in photonics for the first time."
In both artificial and biological systems, these nodes only "fire" once a threshold is reached - a nonlinear process that allows small changes in input to cause larger, more complex changes in output.
Without that nonlinearity, adding layers does nothing: the system just reduces to a single-layer linear operation, where inputs are simply added together, and no real learning occurs.
While many research teams, including teams at Penn Engineering, have developed light-powered chips capable of handling linear mathematical operations, none has solved the challenge of representing nonlinear functions using only light - until now.
"Without nonlinear functions, photonic chips can't train deep networks or perform truly intelligent tasks," says Tianwei Wu (Gr'24), a postdoctoral fellow in ESE and the paper's first author.
An image of the light inside the chip - the white dashed boxes are the inputs and the yellow dashed boxes the outputs. By changing the shape and intensity of the pump beam, the team can control how the signal light is absorbed, transmitted or amplified, depending on its intensity and the material's behavior. This process "programs" the chip to perform different nonlinear functions.
"We're not changing the chip's structure," says Feng. "We're using light itself to create patterns inside the material, which then reshapes how the light moves through it."
The result is a reconfigurable system that can express a wide range of mathematical functions depending on the pump pattern. That flexibility allows the chip to learn in real time, adjusting its behavior based on feedback from its output.
In both cases, the photonic chip matched or outperformed traditional digital neural networks, but used fewer operations, and did not need power-hungry electronic components.
In one striking result, just four nonlinear optical connections on the chip were equivalent to 20 linear electronic connections with fixed nonlinear activation functions in a traditional model. That efficiency hints at what's possible as the architecture scales.
Unlike previous photonic systems - which are fixed after fabrication - the Penn chip starts as a blank canvas. The pump light acts like a brush, drawing reprogrammable instructions into the material.
"This is a true proof-of-concept for a field-programmable photonic computer," says Feng. "It's a step toward a future where we can train AI at the speed of light."
By replacing heat-generating electronics with low-energy optical components, the platform also promises to slash energy consumption in AI data centers - potentially transforming the economics of machine learning.
"This could be the beginning of photonic computing as a serious alternative to electronics," says Liang. "Penn is the birthplace of ENIAC, the world's first digital computer - this chip might be the first real step toward a photonic ENIAC."
Research Report:Field-Programmable Photonic Nonlinearity
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