Deep learning-enabled compact optical trigonometric operator with metasurface

1.
Advanced Microscopy and Instrumentation Research Center, School of Instrumentation Science and Engineering, Harbin Institute of Technology, Harbin, 150080, China
2.
Department of Microwave Engineering, Harbin Institute of Technology, Harbin, 150001, China
3.
LEME, UPL, Univ Paris Nanterre, 92410, Ville d’Avray, France

Funds: This work is supported by Natural Science Foundation of Heilongjiang Province (YQ2021F004), National Natural Science Foundation of China (Nos. 61871152 and 62171153).

摘要

- /
- /
Abstract: In this paper, a novel strategy based on a metasurface composed of simple and compact unit cells to achieve ultra-high-speed trigonometric operations under specific input values is theoretically and experimentally demonstrated. An electromagnetic wave (EM)-based optical diffractive neural network with only one hidden layer is physically built to perform four trigonometric operations (sine, cosine, tangent, and cotangent functions). Under the unique composite input mode strategy, the designed optical trigonometric operator responds to incident light source modes that represent different trigonometric operations and input values (within one period), and generates correct and clear calculated results in the output layer. Such a wave-based operation is implemented with specific input values, and the proposed concept work may offer breakthrough inspiration to achieve integrable optical computing devices and photonic signal processors with ultra-fast running speeds.
- Optical trigonometric operations /
- Metasurface /
- Diffractive neural network

HTML全文

参考文献(38)

[1]	Considine V. CORDIC trigonometric function generator for DSP. In: International Conference on Acoustics, Speech, and Signal Processing. 1989;4:2381–4.
[2]	Tian-li L, Tao Y, Xing W, Hai-gang Y. An efficient single-precision floating-point trigonometric function calculation circuit structure and implementation. Microelectronics & Computer. 2018;35:33–7.
[3]	Ma S, Wang Z. Rapid computation of trigonometric function on DSP. Comput Eng. 2005;31:12–4.
[4]	Price DDS. A history of calculating machines. IEEE Micro. 1984;4:22–52.
[5]	Clymer AB. The mechanical analog computers of Hannibal Ford and William Newell. IEEE Annals Hist Comput. 1993;15:19–34.
[6]	Wu J, Lin X, Guo Y, Liu J, Fang L, Jiao S, et al. Analog Optical Computing for Artificial Intelligence. Engineering. 2021;10:133-45.
[7]	Zangeneh-Nejad F, Sounas DL, Alù A, Fleury R. Analogue computing with metamaterials. Nat Rev Mater. 2020;6:207–25.
[8]	Slav´ık R, Park Y, Ayotte N, Doucet S, Ahn TJ, LaRochelle S, et al. Photonic temporal integrator for all-optical computing. Opt Express. 2008;16:18202–14.
[9]	Michalska M, Swiderski J, Mamajek M. Arbitrary pulse shaping in erdoped fiber amplifierspossibilities and limitations. Opt Laser Technol. 2014;60:8–13.
[10]	Ashrafi R, Dizaji MR, Cortés LR, Zhang J, Yao J, Azaña J, et al. Time-delay to intensity mapping based on a second-order optical integrator: application to optical arbitrary waveform generation. Opt Express. 2015;23:16209–23.
[11]	Pérez D, Gasulla I, Crudgington L, Thomson DJ, Khokhar AZ, Ke L, et al. Multipurpose silicon photonics signal processor core. Nat Commun. 2017;8:636.
[12]	Boolakee T, Heide C, Garzón-Ramírez A, Weber HB, Franco I, Hommelhoff P. Light-field control of real and virtual charge carriers. Nature. 2022;605:251–5.
[13]	Zhao W, Liu S, Qi H, Peng G, Shen M. Sampled fiber grating for wdm signal queuing with picosecond time interval. Opt Laser Technol. 2017;97:302–7.
[14]	Ding X, Wang Z, Hu Z, Liu J, Zhang K, Li H, et al. Metasurface holographic image projection based on mathematical properties of Fourier transform. PhotoniX. 2020;1:1–12.
[15]	Lee D, So S, Hu G, Kim M, Badloe T, Cho H, et al. Hyperbolic metamaterials: fusing artificial structures to natural 2D materials. eLight. 2022;2:1–23.
[16]	Wang Z, Hu G, Wang X, Ding X, Zhang K, Li H, et al. Single-layer spatial analog meta-processor for imaging processing. Nat Commun. 2022;13:2188.
[17]	Zhao Z, Ding X, Zhang K, Fu J, Burokur SN, Wu Q. Generation and deflection control of a 2D Airy beam utilizing metasurfaces. Opt Lett. 2021;46:5220–3.
[18]	Hossein B, Zahra K, Somayyeh K, Amin K. Integration in analog optical computing using metasurfaces revisited: toward ideal optical integration. J Opt Soc Am B. 2017;34:1270–9.
[19]	Zhu T, Zhou Y, Lou Y, Ye H, Qiu M, Ruan Z, et al. Plasmonic computing of spatial differentiation. Nat Commun. 2017;8:1–6.
[20]	Zuo SY, Tian Y, Wei Q, Cheng Y, Liu X. Acoustic analog computing based on a reflective metasurface with decoupled modulation of phase and amplitude. J Appl Phys. 2018;123:091704.
[21]	Fu W, Zhao D, Li Z, Liu S, Tian C, Huang K. Ultracompact meta-imagers for arbitrary all-optical convolution. Light Sci Appl. 2022;11:1–13.
[22]	Kwon H, Sounas D, Cordaro A, Polman A, Alù A. Nonlocal metasurfaces for optical signal processing. Phys Rev Lett. 2018;121: 173004.
[23]	Huo P, Zhang C, Zhu W, Liu M, Zhang S, Zhang S, Xu T. Photonic spin-multiplex-ing metasurface for switchable spiral phase contrast imaging. Nano Lett. 2020;20:2791–8.
[24]	Wang Z, Chang L, Wang F, Li T, Gu T. Integrated photonic metasystem for image classifications at telecommunication wavelength. Nat Commun. 2022;13:1–8.
[25]	Cordaro A, Edwards B, Nikkhah V, Alù A, Engheta N, Polman A. Solving integral equations in free-space with inverse-designed ultrathin optical metagratings. 2022. arXiv preprint arXiv:2202.05219.
[26]	Zhang W, Qu C, Zhang X. Solving constant-coefficient differential equations with dielectric metamaterials. J Opt. 2016;18: 075102.
[27]	Zhao Z, Wang Y, Ding X, Li H, Fu J, Zhang K, et al. Compact logic operator utilizing a single-layer metasurface. Photon Res. 2022;10:316–22.
[28]	Qian C, Lin X, Lin X, Xu J, Sun Y, Li E, Chen H. Performing optical logic operations by a diffractive neural network. Light Sci Appl. 2020;9:1–7.
[29]	Lin W, Chen L, Chen Y, Cai W, Hu Y, Wen K. Single-shot speckle reduction by eliminating redundant speckle pattern in digital holography. Appl Opt. 2020;59:5066–72.
[30]	Luo Y, Zhao Y, Li J, Çetintaş E, Rivenson Y, Jarrahi M, Ozcan A. Computational imaging without a computer: seeing through random diffusers at the speed of light. eLight. 2022;2:1–16.
[31]	Qian C, Zheng B, Shen Y, Jing L, Li E, Shen L, Chen H. Deep-learning-enabled self-adaptive microwave cloak without human intervention. Nat Photonics. 2020;14:383–90.
[32]	Lin X, Rivenson Y, Yardimci NT, Veli M, Luo Y, Jarrahi M, et al. All-optical machine learning using diffractive deep neural networks. Science. 2018;361:1004–8.
[33]	Lin R, Alnakhli Z, Li X. Engineering of multiple bound states in the continuum by latent representation of freeform structures. Photon Res. 2021;9:B96–103.
[34]	Ren H, Shao W, Li Y, Salim F, Gu M. Three-dimensional vectorial holography based on machine learning inverse design. Sci Adv. 2020;6:eaaz4261.
[35]	Khoram E, Chen A, Liu D, Ying L, Wang Q, Yuan M, et al. Nanophotonic media for artificial neural inference. Photon Res. 2019;7:823–7.
[36]	Wu Z, Zhou M, Khoram E, Liu B, Yu Z. Neuromorphic metasurface. Photon Res. 2020;8:46–50.
[37]	Rahman MSS, Li J, Mengu D, Rivenson Y, Ozcan A. Ensemble learning of diffractive optical networks. Light Sci Appl. 2020;10:1–13.
[38]	Li Z, Cheng H, Liu Z, Chen S, Tian J. Plasmonic airy beam generation by both phase and amplitude modulation with metasurfaces. Adv Opt Mater. 2016;4:1230–5.

施引文献

资源附件(0)

点击查看大图

计量

文章访问数: 127
HTML全文浏览量: 0
PDF下载量: 0
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

留言板

doi: 10.1186/s43074-022-00062-4

计量

Deep learning-enabled compact optical trigonometric operator with metasurface

计量

目录

PhotoniX

联系我们

友情链接

留言板

doi: 10.1186/s43074-022-00062-4

计量

出版历程

Deep learning-enabled compact optical trigonometric operator with metasurface

计量

出版历程

目录

PhotoniX

联系我们

友情链接