Spatial-Dependent Hamiltonian Formulation of Cross-Mode Modulation

Yang, Haofan; Xiong, Zhongfei; Hu, Hanwen; Chen, Yuntian; Zhang, Chi; Xu, Jing

doi:10.1109/jphot.2019.2960091

IEEE Photonics J.

2020

DOI: 10.1109/jphot.2019.2960091

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Spatial-Dependent Hamiltonian Formulation of Cross-Mode Modulation

Haofan Yang

Zhongfei Xiong

Hanwen Hu

et al.

Abstract: In the absence of random mode mixing (RMM), linearization of the cross-mode modulation (XMM) under pump-probe configuration is in general complicated because the evolution of the pump light depends on the local mode decomposition of itself. In this work, general derivation of the Hamiltonian of the XMM system without RMM is carried out and discussed under two interesting scenarios where the pump evolution can be effectively linearized, leading to spatial dependent Hamiltonian of the probe light. Representative… Show more

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“…1 Coupled Nonlinear Ring Resonator Lattice. We begin with the analysis of the cross-mode modulation (XMM) [37,38] between two pump lights (CW with complex amplitude of p and CCW with complex amplitude q at the same frequency 1…”

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confidence: 99%

Optically Reconfigurable Spin-Valley Hall Effect of Light in Coupled Nonlinear Ring Resonator Lattice

Yang

Xiong

et al. 2021

Phys. Rev. Lett.

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Scattering immune propagation of light in topological photonic systems may revolutionarize the design of integrated photonic circuits for information processing and communications. In optics, various photonic topological circuits have been developed, which were based on classical emulation of either quantum spin Hall effect or quantum valley Hall effect. On the other hand, the combination of both the valley and spin degrees of freedom can lead to a new kind of topological transport phenomenon, dubbed quantum spin valley Hall effect (QSVH), which can further expand the number of topologically protected edge channels and would be useful for information multiplexing. However, it is challenging to realize QSVH in most known material platforms, due to the requirement of breaking both the (pseudo-)fermionic time-reversal ( ) and parity symmetries ( ) individually, but leaving the combined symmetry  intact. Here, we propose an experimentally feasible platform to realize QSVH for light, based on coupled ring resonators mediated by optical Kerr nonlinearity. Thanks to the inherent flexibility of cross-mode modulation (XMM), the coupling between the probe light can be engineered in a controllable way such that spin-dependent staggered sublattice potential emerges in the effective Hamiltonian. With delicate yet experimentally feasible pump conditions, we show the existence of spin valley Hall induced topological edge states. We further demonstrate that both degrees of freedom, i.e., spin and valley, can be manipulated simultaneously in a reconfigurable manner to realize spin-valley photonics, doubling the degrees of freedom for enhancing the information capacity in optical communication systems.

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confidence: 99%

Optically Reconfigurable Spin-Valley Hall Effect of Light in Coupled Nonlinear Ring Resonator Lattice

Yang

Xiong

et al. 2021

Phys. Rev. Lett.

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Handwritten digit recognition by three-layer diffractive neural network

Xu¹,

Xu²,

Yang³

et al. 2022

Acta Phys. Sin.

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ODNN (Optical diffractive neural network) uses light wave as a computing medium to perform the inference and prediction function of neural network, which has the advantages of high speed, low power consumption, and parallel processing. In this paper, an ODNN with only three layers of phase modulation is designed, and a method to improve the recognition performance of ODNN based on the first-order spectral distribution of targets is proposed. Using this method, the parameters of a three-layer ODNN are effectively optimized and the optimal pixel size, diffraction distance, and method for image preprocessing are obtained. The three-layer ODNN designed in this paper has a recognition accuracy rate of 95.3% for MNIST (handwritten digit set), compared with the 91.73% accuracy achieved by the five-layer ODNN in the reference. In addition, the system volume is greatly reduced and the system structure is simplified. Combined with the advantages of high speed and low power consumption, it has huge application potential in fields such as edge computing in the future.

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Spatial-Dependent Hamiltonian Formulation of Cross-Mode Modulation

Cited by 2 publications

References 16 publications

Optically Reconfigurable Spin-Valley Hall Effect of Light in Coupled Nonlinear Ring Resonator Lattice

Optically Reconfigurable Spin-Valley Hall Effect of Light in Coupled Nonlinear Ring Resonator Lattice

Handwritten digit recognition by three-layer diffractive neural network

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