Litcius/Paper detail

Neuromorphic Computing Based on Wavelength-Division Multiplexing

Xingyuan Xu, Weiwei Han, Mengxi Tan, Yang Sun, Yang Li, Jiayang Wu, Roberto Morandotti, Arnan Mitchell, Kun Xu, David Moss

2022IEEE Journal of Selected Topics in Quantum Electronics190 citationsDOIOpen Access PDF

Abstract

Optical neural networks (ONNs), or optical neuromorphic hardware accelerators, have the potential to dramatically enhance the computing power and energy efficiency of mainstream electronic processors, due to their ultralarge bandwidths of up to 10s of terahertz together with their analog architecture that avoids the need for reading and writing data back and forth. Different multiplexing techniques have been employed to demonstrate ONNs, amongst which wavelength division multiplexing (WDM) techniques make sufficient use of the unique advantages of optics in terms of broad bandwidths. Here, we review recent advances in WDM based ONNs, focusing on methods that use integrated microcombs to implement ONNs. We present results for human image processing using an optical convolution accelerator operating at 11 Tera operations per second. The open challenges and limitations of ONNs that need to be addressed for future applications are also discussed.

Topics & Concepts

Neuromorphic engineeringComputer scienceMultiplexingWavelength-division multiplexingTime-division multiplexingComputer architectureElectronic engineeringFrequency-division multiplexingOptical computingEfficient energy useComputer hardwareTelecommunicationsArtificial neural networkElectrical engineeringOrthogonal frequency-division multiplexingOpticsWavelengthArtificial intelligencePhysicsEngineeringChannel (broadcasting)Neural Networks and Reservoir ComputingOptical Network TechnologiesPhotonic and Optical Devices
Neuromorphic Computing Based on Wavelength-Division Multiplexing | Litcius