Your search keyword '"Yu, Zeqing"' showing total 3 results

1. Neural‐Optic Co‐Designed Polarization‐Multiplexed Metalens for Compact Computational Spectral Imaging.

Author

Zhang, Qiangbo, Lin, Peicheng, Wang, Chang, Zhang, Yang, Yu, Zeqing, Liu, Xinyu, Lu, Yanqing, Xu, Ting, and Zheng, Zhenrong

Subjects

SPECTRAL imaging, DIFFRACTIVE optical elements, IMAGING systems, AUGMENTED reality

Abstract

In the expanding fields of mobile technology and augmented reality, there is a growing demand for compact, high‐fidelity spectral imaging systems. Traditional spectral imaging techniques face limitations due to their size and complexity. Diffractive optical elements (DOEs), although helpful in reducing size, primarily modulate the phase of light. Here, an end‐to‐end computational spectral imaging framework based on polarization‐multiplexed metalens is introduced. A distinguishing feature of this approach lies in its capacity to simultaneously modulate orthogonal polarization channels. When harnessed in conjunction with a neural network, it facilitates the attainment of high‐fidelity spectral reconstruction. Importantly, the framework is intrinsically fully differentiable, a feature that permits the joint optimization of both the metalens structure and the parameters governing the neural network. The experimental results presented herein validate the exceptional spatial‐spectral reconstruction performance, underscoring the efficacy of this system in practical, real‐world scenarios. This innovative approach transcends the traditional boundaries separating hardware and software in the realm of computational imaging and holds the promise of substantially propelling the miniaturization of spectral imaging systems. [ABSTRACT FROM AUTHOR]

Published

2024

2. Dual-Channel Switchable Metasurface Filters for Compact Spectral Imaging with Deep Compressive Reconstruction.

Author

Wang, Chang, Liu, Xinyu, Zhang, Yang, Sun, Yan, Yu, Zeqing, and Zheng, Zhenrong

Subjects

SPECTRAL imaging, NEMATIC liquid crystals, OBJECT recognition (Computer vision), IMAGING systems, LINEAR polarization, IMAGE sensors

Abstract

Spectral imaging technology, which aims to capture images across multiple spectral channels and create a spectral data cube, has been widely utilized in various fields. However, conventional spectral imaging systems face challenges, such as slow acquisition speed and large size. The rapid development of optical metasurfaces, capable of manipulating light fields versatilely and miniaturizing optical components into ultrathin planar devices, offers a promising solution for compact hyperspectral imaging (HSI). This study proposes a compact snapshot compressive spectral imaging (SCSI) system by leveraging the spectral modulations of metasurfaces with dual-channel switchable metasurface filters and employing a deep-learning-based reconstruction algorithm. To achieve compactness, the proposed system integrates dual-channel switchable metasurface filters using twisted nematic liquid crystals (TNLCs) and anisotropic titanium dioxide (TiO2) nanostructures. These thin metasurface filters are closely attached to the image sensor, resulting in a compact system. The TNLCs possess a broadband linear polarization conversion ability, enabling the rapid switching of the incidence polarization state between x-polarization and y-polarization by applying different voltages. This polarization conversion facilitates the generation of two groups of transmittance spectra for wavelength-encoding, providing richer information for spectral data cube reconstruction compared to that of other snapshot compressive spectral imaging techniques. In addition, instead of employing classic iterative compressive sensing (CS) algorithms, an end-to-end residual neural network (ResNet) is utilized to reconstruct the spectral data cube. This neural network leverages the 2-frame snapshot measurements of orthogonal polarization channels. The proposed hyperspectral imaging technology demonstrates superior reconstruction quality and speed compared to those of the traditional compressive hyperspectral image recovery methods. As a result, it is expected that this technology will have substantial implications in various domains, including but not limited to object detection, face recognition, food safety, biomedical imaging, agriculture surveillance, and so on. [ABSTRACT FROM AUTHOR]

Published

2023

3. Superpixel-based linear reconstruction method for dual-camera compressed hyperspectral imaging system.

Author

Chen, Bingliang, Zhang, Yang, Yu, Zeqing, Liu, Xinyu, Zhang, Qiangbo, Wang, Chang, and Zheng, Zhenrong

Subjects

*HYPERSPECTRAL imaging systems, *SPECTRAL imaging, *SPECTRAL sensitivity, *IMAGING systems, *VECTOR spaces, *RADIANT intensity

Abstract

Compressive spectral imaging systems have received significant research attention in recent years. Among these systems, the dual-camera compressive hyperspectral imaging (DCCHI) design, has the potential to improve imaging resolution while maintaining the snapshot advantage. In this paper, we propose superpixel-based linear reconstruction methods for DCCHI system. Specifically, we assume that the spectral intensity of the superpixels generated from the RGB image varies linearly in the spectral dimension. Instead of addressing an ill-posed problem, we reconstruct hyperspectral images via solving overdetermined equations using the least squares method, resulting in a significant reduction in both computation time and memory usage. To further enhance the reconstruction accuracy, we extend the spectra of superpixels from a 1D linear space into a 3D space with an RGB spectral response matrix. Despite the simplicity of our method, it offers improved reconstruction accuracy of hyperspectral images compared to other state-of-the-art methods. Furthermore, it is more efficient in terms of memory usage and computational time. • We propose a fast and memory-efficient spectral reconstruction framework for DCCHI. • The method is easier to implement than traditional or deep learning methods. • The proposed method possesses superior performance of reconstruction accuracy. [ABSTRACT FROM AUTHOR]

Published

2023