Author(s): Li, ZX (Li, Zhexin); Zheng, YQ (Zheng, Yiqiang); Li, LL (Li, Linlin); Liu, LC (Liu, Lingchen); Lou, Z (Lou, Zheng); Wang, LL (Wang, Lili)

Source: ADVANCED FUNCTIONAL MATERIALS DOI: 10.1002/adfm.202304119  Early Access Date: AUG 2023  

Abstract: The image degradation owing to the absorption and scattering of optical propagation medium makes the non-visualization and anamorphose in real image. The complex algorithms based on highly integrated hardware can restore degraded image while it causes inefficient serial operation and storage redundancy. One improved strategy is to parallel functional integration in front-end visual perceptron. Here, a parallel photoelectron storage and visual preprocessing in nanowire perceptron to synchronously achieve image perception, visual memory, and in-sensor preprocessing are demonstrated. This functional integration is originated from charge-resolved storage in temporal or frequency domain under optical pulsed excitation due to cascaded defect engineering. The proposed system enhances the peak signal-to-noise ratio (PSNR) of degraded image from 152 to 181 dB by feature decompression and also has 7.2% of PSNR improvement by noise filtration. This system is validated to improved train accuracy of back-end artificial neural network (ANN) by 32.8% and shorten its iteration period by 77.4%.

Parallel photoelectron storage and visual preprocessing in nanowire phototransistor array called nanowire phototransistor array (NPTA) synchronously achieve image perception, visual memory, and in-sensor preprocessing for image degradation. The proposed system improves peak signal-to-noise ratio (PSNR) of degraded image from 152 to 181 dB by feature decompression and also has 7.2% of PSNR improvement by noise filtration. image

Accession Number: WOS:001152104500001

ISSN: 1616-301X

eISSN: 1616-3028