Simulating single-photon detector array sensors for depth imaging

Scholes, Stirling; Mora-Martín, Germán; Zhu, Feng; Gyöngy, István; Soan, P. J.; Leach, Jonathan

doi:10.21203/rs.3.rs-2238499/v1

Cited by 2 publications

(1 citation statement)

References 60 publications

(62 reference statements)

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“…Inspired by the excellent work of Scholes S. et al [ 14 ], we design our underwater SPAD simulation based on Fisher information. Fisher information is a crucial concept in statistics, used to measure the uncertainty about a parameter in probability distribution parameter estimation.…”

Section: Theory Of Underwater Spad Imaging Simulationmentioning

confidence: 99%

A Simulation Method for Underwater SPAD Depth Imaging Datasets

Lu,

Qiu,

Wang

et al. 2024

Sensors

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In recent years, underwater imaging and vision technologies have received widespread attention, and the removal of the backward-scattering interference caused by impurities in the water has become a long-term research focus for scholars. With the advent of new single-photon imaging devices, single-photon avalanche diode (SPAD) devices, with high sensitivity and a high depth resolution, have become cutting-edge research tools in the field of underwater imaging. However, the high production costs and small array areas of SPAD devices make it very difficult to conduct underwater SPAD imaging experiments. To address this issue, we propose a fast and effective underwater SPAD data simulation method and develop a denoising network for the removal of backward-scattering interference in underwater SPAD images based on deep learning and simulated data. The experimental results show that the distribution difference between the simulated and real underwater SPAD data is very small. Moreover, the algorithm based on deep learning and simulated data for the removal of backward-scattering interference in underwater SPAD images demonstrates effectiveness in terms of both metrics and human observation. The model yields improvements in metrics such as the PSNR, SSIM, and entropy of 5.59 dB, 9.03%, and 0.84, respectively, demonstrating its superior performance.

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Section: Theory Of Underwater Spad Imaging Simulationmentioning

confidence: 99%

A Simulation Method for Underwater SPAD Depth Imaging Datasets

Lu,

Qiu,

Wang

et al. 2024

Sensors

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Underwater Single-Photon 3D Reconstruction Algorithm Based on K-Nearest Neighbor

Wang,

Qiu,

et al. 2024

Sensors

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The high sensitivity and picosecond time resolution of single-photon avalanche diodes (SPADs) can improve the operational range and imaging accuracy of underwater detection systems. When an underwater SPAD imaging system is used to detect targets, backward-scattering caused by particles in water often results in the poor quality of the reconstructed underwater image. Although methods such as simple pixel accumulation have been proven to be effective for time–photon histogram reconstruction, they perform unsatisfactorily in a highly scattering environment. Therefore, new reconstruction methods are necessary for underwater SPAD detection to obtain high-resolution images. In this paper, we propose an algorithm that reconstructs high-resolution depth profiles of underwater targets from a time–photon histogram by employing the K-nearest neighbor (KNN) to classify multiple targets and the background. The results contribute to the performance of pixel accumulation and depth estimation algorithms such as pixel cross-correlation and ManiPoP. We use public experimental data sets and underwater simulation data to verify the effectiveness of the proposed algorithm. The results of our algorithm show that the root mean square errors (RMSEs) of land targets and simulated underwater targets are reduced by 57.12% and 23.45%, respectively, achieving high-resolution single-photon depth profile reconstruction.

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Simulating single-photon detector array sensors for depth imaging

Cited by 2 publications

References 60 publications

A Simulation Method for Underwater SPAD Depth Imaging Datasets

A Simulation Method for Underwater SPAD Depth Imaging Datasets

Underwater Single-Photon 3D Reconstruction Algorithm Based on K-Nearest Neighbor

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