Design and experimental verification for optical module of optical vector–matrix multiplier

Zhu, Wenyue; Zhang, Lei; Lü, Yangyang; Zhou, Peng; Yang, Lin

doi:10.1364/ao.52.004412

Cited by 15 publications

(6 citation statements)

References 14 publications

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“…The first kind of optical MVM (PLC-MVM) is implemented by the diffraction of light in free space. Figure 1a shows a typical MVM configuration 34 , 35 . First, the incident vector of X distributed along the x direction can be expanded and replicated along the y direction through a cylindrical lens or other optical elements.…”

Section: Matrix-vector Multiplicationmentioning

confidence: 99%

Photonic matrix multiplication lights up photonic accelerator and beyond

et al. 2022

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Matrix computation, as a fundamental building block of information processing in science and technology, contributes most of the computational overheads in modern signal processing and artificial intelligence algorithms. Photonic accelerators are designed to accelerate specific categories of computing in the optical domain, especially matrix multiplication, to address the growing demand for computing resources and capacity. Photonic matrix multiplication has much potential to expand the domain of telecommunication, and artificial intelligence benefiting from its superior performance. Recent research in photonic matrix multiplication has flourished and may provide opportunities to develop applications that are unachievable at present by conventional electronic processors. In this review, we first introduce the methods of photonic matrix multiplication, mainly including the plane light conversion method, Mach–Zehnder interferometer method and wavelength division multiplexing method. We also summarize the developmental milestones of photonic matrix multiplication and the related applications. Then, we review their detailed advances in applications to optical signal processing and artificial neural networks in recent years. Finally, we comment on the challenges and perspectives of photonic matrix multiplication and photonic acceleration.

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Section: Matrix-vector Multiplicationmentioning

confidence: 99%

Photonic matrix multiplication lights up photonic accelerator and beyond

et al. 2022

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“…Moreover, benefiting from the quickly developed liquid-crystal-on-silicon (LCoS) technology and driving from the display industry, the resolution of SLM or DMD becomes fairly large (4 K resolution is commercially available). But the crosstalk error is the main obstacle to demonstrate the utmost performance of VMM employing high resolution SLM or DMD [36]. Though the crosstalk issue could be circumvented by enlarging the pixel size of SLM or DMD, the functional area of SLM or DMD restricts Here, V, Σ and U represent a unitary matrix, a diagonal matrix and a unitary matrix, respectively.…”

Section: Vmm-vector Matrix Multipliermentioning

confidence: 99%

The challenges of modern computing and new opportunities for optics

Zhang

et al. 2021

PhotoniX

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In recent years, the explosive development of artificial intelligence implementing by artificial neural networks (ANNs) creates inconceivable demands for computing hardware. However, conventional computing hardware based on electronic transistor and von Neumann architecture cannot satisfy such an inconceivable demand due to the unsustainability of Moore’s Law and the failure of Dennard’s scaling rules. Fortunately, analog optical computing offers an alternative way to release unprecedented computational capability to accelerate varies computing drained tasks. In this article, the challenges of the modern computing technologies and potential solutions are briefly explained in Chapter 1. In Chapter 2, the latest research progresses of analog optical computing are separated into three directions: vector/matrix manipulation, reservoir computing and photonic Ising machine. Each direction has been explicitly summarized and discussed. The last chapter explains the prospects and the new challenges of analog optical computing.

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“…Metasurfaces in particular have been proven to perform all-optical matrix calculations through the ability to manipulate the properties of light at defined spatial locations through the correct design of subwavelength-sized meta-atoms 101 – 103 This functionality is extremely important in the field of machine learning, where models are trained through a combination of matrix multiplications and backpropagation.…”

Section: All-optical Machine Learningmentioning

confidence: 99%

Computation at the speed of light: metamaterials for all-optical calculations and neural networks

2022

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The explosion in the amount of information that is being processed is prompting the need for new computing systems beyond existing electronic computers. Photonic computing is emerging as an attractive alternative due to performing calculations at the speed of light, the change for massive parallelism, and also extremely low energy consumption. We review the physical implementation of basic optical calculations, such as differentiation and integration, using metamaterials, and introduce the realization of all-optical artificial neural networks. We start with concise introductions of the mathematical principles behind such optical computation methods and present the advantages, current problems that need to be overcome, and the potential future directions in the field. We expect that our review will be useful for both novice and experienced researchers in the field of all-optical computing platforms using metamaterials.

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Design and experimental verification for optical module of optical vector–matrix multiplier

Cited by 15 publications

References 14 publications

Photonic matrix multiplication lights up photonic accelerator and beyond

Photonic matrix multiplication lights up photonic accelerator and beyond

The challenges of modern computing and new opportunities for optics

Computation at the speed of light: metamaterials for all-optical calculations and neural networks

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