Progress in Bioinspired Photodetectors Design for Visual Information Processing

Rapid development of modern science and technology has prompted explosive growth of data volumes, especially the visual information, which brings heavy pressure on information processing and computation. The classic technical route to improve the computation power of image processing units by reduci...

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Bibliographic Details
Published in:Advanced functional materials 2023-10, Vol.33 (40), p.n/a
Main Authors: Wu, Yi, Deng, Wenjie, Wang, Xiaoting, Yu, Wenjing, Chen, Zhijie, Chen, Xiaoqing, Li, Jingzhen, Chai, Yang, Zhang, Yongzhe
Format: Article
Language:English
Subjects:
bioinspired materials
Biological properties
Biomimetics
Computation
Data processing
Image processing
Information processing
in‐sensor computing
Luminous intensity
machine vision
Materials science
Moore's law
photodetectors
Photometers
Retina
Transistors
Vision systems
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Summary:Rapid development of modern science and technology has prompted explosive growth of data volumes, especially the visual information, which brings heavy pressure on information processing and computation. The classic technical route to improve the computation power of image processing units by reducing the critical dimension of the transistors according to Moore's law gradually fails due to the physical limit of transistors’ footprint and the separated architectures. Inspired by human vision systems, retina‐like photodetectors that mimic their spatial and temporal properties have attracted widespread attention. These developed architectures enable the early data processing in‐ or near‐sensor, significantly reducing the computing power required in the back end. Herein, a comprehensive review on bioinspired photodetectors that possess the spatial and temporal properties of biological vision is provided. The properties of retina are summarized and presented first. Basic structure design and operation mechanism of those photodetectors with spatial properties of retina (including the distribution of receptive fields and the shape of the hemisphere) and temporal properties of retina (including the memory properties enabled learning and the light intensity adaptation) are reviewed thoroughly. Eventually, challenges and future perspectives are commented and provided to facilitate the rapid development of in‐ or near‐sensor computing photodetectors. Bioinspired photodetectors have the potential to break the computing power bottleneck for image processing. In this review, the spatial and temporal properties of the biological vision are first introduced. Then, the basic structure design and operation mechanism of the photodetectors with biological inspired spatial and temporal properties are thoroughly reviewed, followed by the outlook of bioinspired photodetectors.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202302899