Photonic matrix multiplication lights up photonic accelerator and beyond

Zhou, Hailong; Dong, Jianji; Cheng, Junwei; Dong, Wenchao; Huang, Chaoran; Shen, Yichen; Zhang, Qiming; Gu, Miṅ; Qian, Chao; Chen, Hongsheng; Ruan, Zhichao; Zhang, Chi

doi:10.1038/s41377-022-00717-8

Cited by 235 publications

(110 citation statements)

References 170 publications

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“…With the increasing global demand for machine learning and computing in general, using light to perform computation has been a rapidly growing focus area of optics and photonics 1 – 5 . The research on optical computing has a long history spanning decades of exciting research and development efforts 6 – 31 .…”

Section: Introductionmentioning

confidence: 99%

Polarization multiplexed diffractive computing: all-optical implementation of a group of linear transformations through a polarization-encoded diffractive network

Hung

Kulce

et al. 2022

Light Sci Appl

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Research on optical computing has recently attracted significant attention due to the transformative advances in machine learning. Among different approaches, diffractive optical networks composed of spatially-engineered transmissive surfaces have been demonstrated for all-optical statistical inference and performing arbitrary linear transformations using passive, free-space optical layers. Here, we introduce a polarization-multiplexed diffractive processor to all-optically perform multiple, arbitrarily-selected linear transformations through a single diffractive network trained using deep learning. In this framework, an array of pre-selected linear polarizers is positioned between trainable transmissive diffractive materials that are isotropic, and different target linear transformations (complex-valued) are uniquely assigned to different combinations of input/output polarization states. The transmission layers of this polarization-multiplexed diffractive network are trained and optimized via deep learning and error-backpropagation by using thousands of examples of the input/output fields corresponding to each one of the complex-valued linear transformations assigned to different input/output polarization combinations. Our results and analysis reveal that a single diffractive network can successfully approximate and all-optically implement a group of arbitrarily-selected target transformations with a negligible error when the number of trainable diffractive features/neurons (N) approaches $$N_pN_iN_o$$ N p N i N o , where Ni and No represent the number of pixels at the input and output fields-of-view, respectively, and Np refers to the number of unique linear transformations assigned to different input/output polarization combinations. This polarization-multiplexed all-optical diffractive processor can find various applications in optical computing and polarization-based machine vision tasks.

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Section: Introductionmentioning

confidence: 99%

Polarization multiplexed diffractive computing: all-optical implementation of a group of linear transformations through a polarization-encoded diffractive network

Hung

Kulce

et al. 2022

Light Sci Appl

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“…Whereas the metamaterials kernels are iteratively optimized beforehand on computer, we can even apply in-situ training on the integrated photonics platform [39], in conjunction with reinforcement learning and other heuristic algorithms [14]. We anticipate that this formalism may be carried over to other enticing applications in on-chip signal processing and neuromorphic computing to drastically reduce their footprints without compromising the efficiency or functionality [40,41].…”

Section: Discussionmentioning

confidence: 99%

Solving Multivariable Equations with Tandem Metamaterialkernels

Tan¹,

Qian²,

Cai³

et al. 2022

PIER

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A fundamental building block in characterizing and tackling scientific and industrial questions boils down to the ability of quickly solving mathematical equations. However, with the ever-growing volume of information and unsustainable integration growth in electronic processors, a radically new modality for solving equations is highly imminent. Here, we introduce an electromagnetic counterpart to solve multivariable complex equations, where two metamaterial kernels are connected in series to form a closed-loop electromagnetic system. Complex valued information is carried by electromagnetic fields, and the equation solution for arbitrary input signals can be recursively attained after a number of feedbacks. As an illustration, we present the capability of such a system in solving eight complex equations, and inversely design two 4×4 metamaterial kernels by topology optimization, whose average element error is reduced to smaller than 10 −4 . Having accomplished all unknown coefficients with high fidelity, our work represents a conspicuous apparatus for a myriad of enticing applications in ultracompact signal processing and neuromorphic computing.

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“…Photonic Tensor Core can be implemented in multiple ways and architectures, 12 here we look at the two most major architectures for Silicon Photonics, based on the mathematical approach used. The architecture reflects the one presented by Lightmatter, where the decomposition is visible.…”

Section: Architecturesmentioning

confidence: 99%

Photonic tensor core for machine learning: a review

Peserico

Shastri

et al. 2022

Emerging Topics in Artificial Intelligence (ETAI) 2022

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Photonic Tensor Core circuits have been widely explored as possible hardware accelerators for the next generation of Machine Learning applications, due to the large bandwidth, low latency, and energy saving that light has. Many architectures have been presented, especially exploiting photonic integrated circuits. However, most of the proposed solutions lack some features, such as integration, scalability, or energy saving. In this paper, we review the major achievements in recent years, showing how high integration can lead to better performance, but it could also limit the scalability of the overall system.

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Photonic matrix multiplication lights up photonic accelerator and beyond

Cited by 235 publications

References 170 publications

Polarization multiplexed diffractive computing: all-optical implementation of a group of linear transformations through a polarization-encoded diffractive network

Polarization multiplexed diffractive computing: all-optical implementation of a group of linear transformations through a polarization-encoded diffractive network

Solving Multivariable Equations with Tandem Metamaterialkernels

Photonic tensor core for machine learning: a review

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