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26 Aug 2025
Harvard SEAS develops digital-to-analog converter bridging electronics and photonics.
Addressing a major roadblock in next-generation photonic computing and signal processing systems, researchers in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have created a device that they say ”bridges digital electronic signals and analog light signals in one fluid step”.Based on lithium niobate chips, the new device offers a potential replacement for the ubiquitous but energy-intensive digital-to-analog conversion and electro-optic modulation systems used all over today’s high-speed data networks.
“Optical communication and high-performance computing, including large language models, rely on conversion of massive amounts of data between the electrical domain – used for storage and computation – and the optical domain – used for data transfer,” commented senior author Marko Lončar, the Tiantsai Lin Professor of Electrical Engineering at SEAS. “For photonic technologies to seamlessly integrate with electronic ones, the interfaces between them must be fast and energy-efficient.”
The research is described in Nature Photonics.
Beating the bottlenecks
Today, electronic digital-to-analog converters, followed by electro-optic modulators, accomplish the task of converting digital electronic signals into analog photonic signals, a process that underpins modern transceiver systems in data centers. But such a workflow is often complex, multi-tiered, and can be energy-intensive.
“When you are computing with light, all the energy that you are saving, all the speed that you are getting, tends to be offset by these big, expensive, inefficient electronic boxes that you need to convert digital data into a sine wave, square wave, triangle wave, or any meaningful waveform,” explained co-first author Yunxiang Song, graduate student in the Lončar Lab.
“These things are actually the bottleneck in many types of photonic computing. So the question was, can we design some kind of novel photonic modulator that obviates the need for these electronic digital-to-analog converters?”
The new Harvard device makes use of the efficient electro-optic properties of thin-film lithium niobate, by which it can turn purely digital electronic inputs into analog optical signals at information rates reaching up to 186 gigabits per second. The device could also enable advances in microwave photonics, for example in wireless or radar communications, as it can be combined with photodetection to perform optical-to-electronic conversion for creating radio frequency signals.
Finally, emerging optical computing approaches, or computing using light rather than electrons, are of great interest because photons have the potential to process data in parallel and more efficiently than conventional electronics. “Our work has the potential to address the current bottleneck of computing and data interconnects particularly in AI technologies,” said co-first author Yaowen Hu, former postdoctoral researcher at Harvard SEAS and now assistant professor at Peking University.
Foundry process similar to silicon
To demonstrate that their device handles data with precision and speed, they tested it by optically encoding images from the well-known MNIST dataset, typically used to benchmark photonic computing systems.
The researchers’ device was fabricated using a lithium niobate foundry process, developed by Harvard startup HyperLight Corporation, that mirrors what exists for silicon chips, which are today in every phone and computer and upon which the digital revolution was built. The team thus showed not only that the device works for their particular application, but also that they can make it in a high-volume and low-cost manner, further paving the way for novel photonic technologies that can complement silicon photonics.
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