Spectrally encoded single-pixel machine vision using diffractive networks

Li, Jingxi; Mengü, Deniz; Yardimci, Nezih Tolga; Luo, Yi; Li, Xurong; Veli, Muhammed; Rivenson, Yair; Jarrahi, Mona; Ozcan, Aydogan

doi:10.1126/sciadv.abd7690

Cited by 137 publications

(116 citation statements)

References 60 publications

(64 reference statements)

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“…Hybrid systems that utilize diffractive networks as a front-end of a jointly-trained electronic neural network (back-end) [74] is another exciting future research direction that will make use of the presented framework to see through more complicated, dynamic scatters. Application of the presented framework and the underlying methodology to design broadband diffractive networks [66,67,76] is another exciting future research direction that can be used to reconstruct multi-color images distorted by unknown, random diffusers or other aberration sources. Finally, our results and presented method can be extended to other parts of the electromagnetic spectrum including e.g., visible/infrared wavelengths, and will open up various new applications in biomedical imaging, astronomy, astrophysics, atmospheric sciences, security, robotics, and many others.…”

Section: Discussionmentioning

confidence: 99%

“…Some of the more recent work on imaging through diffusers has also focused on using deep learning methods to digitally recover the images of unknown objects [11,12,48,49]. Deep learning has been re-defining the state-of-the-art across many areas in optics, including optical microscopy [50][51][52][53][54][55], holography [56][57][58][59][60][61], inverse design of optical devices [62][63][64][65][66][67], optical computation and statistical inference [68][69][70][71][72][73][74][75][76][77], among others [78][79][80].…”

Section: Main Textmentioning

confidence: 99%

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Computational imaging without a computer: seeing through random diffusers at the speed of light

Luo

Zhao

et al. 2022

eLight

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107

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Imaging through diffusers presents a challenging problem with various digital image reconstruction solutions demonstrated to date using computers. Here, we present a computer-free, all-optical image reconstruction method to see through random diffusers at the speed of light. Using deep learning, a set of transmissive diffractive surfaces are trained to all-optically reconstruct images of arbitrary objects that are completely covered by unknown, random phase diffusers. After the training stage, which is a one-time effort, the resulting diffractive surfaces are fabricated and form a passive optical network that is physically positioned between the unknown object and the image plane to all-optically reconstruct the object pattern through an unknown, new phase diffuser. We experimentally demonstrated this concept using coherent THz illumination and all-optically reconstructed objects distorted by unknown, random diffusers, never used during training. Unlike digital methods, all-optical diffractive reconstructions do not require power except for the illumination light. This diffractive solution to see through diffusers can be extended to other wavelengths, and might fuel various applications in biomedical imaging, astronomy, atmospheric sciences, oceanography, security, robotics, autonomous vehicles, among many others.

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Section: Discussionmentioning

confidence: 99%

Section: Main Textmentioning

confidence: 99%

Computational imaging without a computer: seeing through random diffusers at the speed of light

Luo

Zhao

et al. 2022

eLight

Self Cite

107

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“…Ultimately, optical setup and computers can be discarded. Ozcan et al introduced an all-optical diffractive NN able to compute a classification task from spatial information of objects [176]. In line with this development, novel all-optical diffractive NNs could perform quantitative measurements (Figure 12c).…”

Section: Current and Future Challengesmentioning

confidence: 93%

Roadmap on Digital Holography-Based Quantitative Phase Imaging

et al. 2021

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Quantitative Phase Imaging (QPI) provides unique means for the imaging of biological or technical microstructures, merging beneficial features identified with microscopy, interferometry, holography, and numerical computations. This roadmap article reviews several digital holography-based QPI approaches developed by prominent research groups. It also briefly discusses the present and future perspectives of 2D and 3D QPI research based on digital holographic microscopy, holographic tomography, and their applications.

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“…In particular, where any unitary transformations can be implemented with conventional optical beamsplitters and phase shifters 35 , a rectangular diagonal matrix can be implemented with optical attenuation achieved by Mach-Zehnder modulator. As well, an OIU implementation that relies on free-space diffractive DNN [36][37][38] has already been shown in the spectral domain 39,40 ). Implementations of optical nonlinearity unit (ONLU) fall into two major categories, one based on optical-to-electrical-to-optical (OEO) and the other on alloptical (AO).…”

Section: Nanophotonic Neural Network Mechanism Of Operationmentioning

confidence: 99%

Ti3C2Tx MXene Enabled All-Optical Nonlinear Activation Function for On-Chip Photonic Deep Neural Networks

Hazan

Ratzker

Zhang

et al. 2021

Preprint

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Neural networks are one of the first major milestones in developing artificial intelligence systems. The utilisation of integrated photonics in neural networks offers a promising alternative approach to microelectronic and hybrid optical-electronic implementations due to improvements in computational speed and low energy consumption in machine-learning tasks. However, at present, most of the neural network hardware systems are still electronic-based due to a lack of optical realisation of the nonlinear activation function. Here, we experimentally demonstrate two novel approaches for implementing an all-optical neural nonlinear activation function based on utilising unique light-matter interactions in 2D Ti3C2Tx (MXene) in the infrared (IR) range in two configurations: 1) a saturable absorber made of MXene thin film, and 2) a silicon waveguide with MXene flakes overlayer. These configurations may serve as nonlinear units in photonic neural networks, while their nonlinear transfer function can be flexibly designed to optimise the performance of different neuromorphic tasks, depending on the operating wavelength. The proposed configurations are reconfigurable and can therefore be adjusted for various applications without the need to modify the physical structure. We confirm the capability and feasibility of the obtained results in machine-learning applications via an Modified National Institute of Standards and Technology (MNIST) handwritten digit classifications task, with near 99% accuracy. Our developed concept for an all-optical neuron is expected to constitute a major step towards the realization of all-optically implemented deep neural networks.

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Spectrally encoded single-pixel machine vision using diffractive networks

Cited by 137 publications

References 60 publications

Computational imaging without a computer: seeing through random diffusers at the speed of light

Computational imaging without a computer: seeing through random diffusers at the speed of light

Roadmap on Digital Holography-Based Quantitative Phase Imaging

Ti3C2Tx MXene Enabled All-Optical Nonlinear Activation Function for On-Chip Photonic Deep Neural Networks

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