Microcomb-driven silicon photonic systems

Shu, Haowen; Chang, Lin; Tao, Yuansheng; Shen, Bitao; Wang, Xie; Jin, Ming; Netherton, Andrew; Tao, Zihan; Zhang, Xuguang; Chen, Ruixuan; Bai, Bowen; Qin, Jun; Yu, Shaohua; Wang, Xingjun; Bowers, John E.

doi:10.1038/s41586-022-04579-3

Cited by 207 publications

(125 citation statements)

References 61 publications

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“…The possible solution is applying a faster adjuster, electro-optic modulation, or thermal deposition to reduce the thermal crosstalk. The integrated turn-key single SMC source [36][37][38], on-chip modulator [39,40], amplifier [41], detector [42], WDM, low-loss waveguide [43,44], optical storage [45], and excellent coupling will promote the implementation of the future-oriented monolithic multi-layer ONN processor and their applications.…”

Section: Discussionmentioning

confidence: 99%

Chip-Based High-Dimensional Optical Neural Network

2022

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Parallel multi-thread processing in advanced intelligent processors is the core to realize high-speed and high-capacity signal processing systems. Optical neural network (ONN) has the native advantages of high parallelization, large bandwidth, and low power consumption to meet the demand of big data. Here, we demonstrate the dual-layer ONN with Mach–Zehnder interferometer (MZI) network and nonlinear layer, while the nonlinear activation function is achieved by optical-electronic signal conversion. Two frequency components from the microcomb source carrying digit datasets are simultaneously imposed and intelligently recognized through the ONN. We successfully achieve the digit classification of different frequency components by demultiplexing the output signal and testing power distribution. Efficient parallelization feasibility with wavelength division multiplexing is demonstrated in our high-dimensional ONN. This work provides a high-performance architecture for future parallel high-capacity optical analog computing.

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Section: Discussionmentioning

confidence: 99%

Chip-Based High-Dimensional Optical Neural Network

2022

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“…Microcombs generated via parametric oscillation in high-Q micro-resonators, are promising optical frequency comb sources, as they offer a large number of wavelengths in integrated platforms. Significant advances have been made in microcombs, leading to a wideband, compact, high-energy-efficiency (even battery driven operation), turnkey and mass-producible comb sources for WDM-based ONNs [173][174][175][176][177][178][179][180][181][182][183].…”

Section: Discussionmentioning

confidence: 99%

Photonic Multiplexing Techniques for Optical Neuromorphic Computing

Moss¹

2022

Preprint

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The simultaneous advances in artificial neural networks and photonic integration technologies have spurred extensive research in optical computing and optical neural networks (ONNs). The potential to simultaneously exploit multiple physical dimensions of time, wavelength and space give ONNs the ability to achieve computing operations with high parallelism and large-data throughput. Different photonic multiplexing techniques based on these multiple degrees of freedom have enabled ONNs with large-scale interconnectivity and linear computing functions. Here, we review the recent advances of ONNs based on different approaches to photonic multiplexing, and present our outlook on key technologies needed to further advance these photonic multiplexing/hybrid-multiplexing techniques of ONNs.

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“…The effort to integrate high-performance optical systems on-chip has made tremendous progress in recent years. Advancements in ultra-low-loss photonic platforms [1], nonlinear photonics [2], and heterogenous material integration [1,3] have enabled fully integrated turnkey frequency comb sources [1,4], on-chip lasers with Hertz linewidth [5], Tbps communications on-chip [6,7], on-chip optical amplifiers [8], and much more. While these systems will continue to improve, a lack of integrated optical isolation limits their performance.…”

Section: Introductionmentioning

confidence: 99%

Integrated Passive Nonlinear Optical Isolators

White¹,

Ahn²,

Gasse³

et al. 2022

Preprint

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Fiber and bulk-optical isolators are widely used to stabilize laser cavities by preventing unwanted feedback. However, their integrated counterparts have been slow to be adopted. While several strategies for onchip optical isolation have been realized, these rely on either integration of magneto-optic materials or high frequency modulation with acoustooptic or electro-optic modulators. Here, we demonstrate an integrated approach for passively isolating a continuous wave laser using the intrinsically non-reciprocal Kerr nonlinearity in ring resonators. Using silicon nitride as a model platform, we achieve single ring isolation of 17-23 dB with 1.8-5.5 dB insertion loss, and a cascaded ring isolation of 35 dB with 5 dB insertion loss. Employing these devices, we demonstrate hybrid integration and isolation with a semi-conductor laser chip.

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Microcomb-driven silicon photonic systems

Cited by 207 publications

References 61 publications

Chip-Based High-Dimensional Optical Neural Network

Chip-Based High-Dimensional Optical Neural Network

Photonic Multiplexing Techniques for Optical Neuromorphic Computing

Integrated Passive Nonlinear Optical Isolators

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