Fundamental limits to depth imaging with single-photon detector array sensors

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

doi:10.1038/s41598-022-27012-1

Cited by 16 publications

(2 citation statements)

References 61 publications

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“…1,2,3 Despite its enormous potential, single-photon LiDAR applications are prohibited by the sparsity of signal photons that are mixed with strong background noise and a very limited imaging frame rate. 4 In this paper, we introduce a novel approach to LiDAR data acquisition and reconstruction, employing a dynamic masking technique in conjunction with an inpainting transformer model.…”

Section: Introductionmentioning

confidence: 99%

Inpainting sparse scenes through physics aware transformers for single-photon LiDAR

McEvoy,

Tafone,

Sua

et al. 2024

Unconventional Optical Imaging IV

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We increase single-photon LiDAR capabilities via a hardware-accelerating inpainting transformer model. This model reconstructs all non-observed information within the image plane as it communicates with the beam steering hardware. We apply this to 3D time-of-flight (ToF) reconstruction, where objects obstruct each other's line of sight. We use ToF histograms to distinguish objects within either the foreground and background, and their overlap will be treated as the dynamic mask for the model to reconstruct. We also employ this to unorthodox scanning patterns such as Lissajous and spiral, which are riddled with sparsity. Lastly, we are developing an AI MEMs system, which intelligently downsamples the image plane based off foreground masks, combating sampling redundancy. We believe that our approach will be useful in applications for imaging and sensing dynamic targets with sparse single-photon data across all domains.

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Section: Introductionmentioning

confidence: 99%

Inpainting sparse scenes through physics aware transformers for single-photon LiDAR

McEvoy,

Tafone,

Sua

et al. 2024

Unconventional Optical Imaging IV

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“…Various methods have been proposed to address the issue of artificial smoke's impact on visualization systems, including Ligh Detection and Ranging (LiDAR) in combination with single-photon imaging systems 1,6,[11][12][13] . These approaches aim to enhance the quality of the image rendered through the cloud, making it possible to identify the target.…”

mentioning

confidence: 99%

Asymmetric imaging through engineered Janus particle obscurants using a Monte Carlo approach for highly asymmetric scattering media

da Mota,

Sadafi,

Mosallaei

2024

Sci Rep

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The advancement of imaging systems has significantly ameliorated various technologies, including Intelligence Surveillance Reconnaissance Systems and Guidance Systems, by enhancing target detection, recognition, identification, positioning, and tracking capabilities. These systems can be countered by deploying obscurants like smoke, dust, or fog to hinder visibility and communication. However, these counter-systems affect the visibility of both sides of the cloud. In this sense, this manuscript introduces a new concept of a smoke cloud composed of engineered Janus particles to conceal the target image on one side while providing clear vision from the other. The proposed method exploits the unique scattering properties of Janus particles, which selectively interact with photons from different directions to open up the possibility of asymmetric imaging. This approach employs a model that combines a genetic algorithm with Discrete Dipole Approximation to optimize the Janus particles' geometrical parameters for the desired scattering properties. Moreover, we propose a Monte Carlo-based approach to calculate the image formed as photons pass through the cloud, considering highly asymmetric particles, such as Janus particles. The effectiveness of the cloud in disguising a target is evaluated by calculating the Probability of Detection (PD) and the Probability of Identification (PID) based on the constructed image. The optimized Janus particles can produce a cloud where it is possible to identify a target more than 50% of the time from one side (PID > 50%) while the target is not detected more than 50% of the time from the other side (PD < 50%). The results demonstrate that the Janus particle-engineered smoke enables asymmetric imaging with simultaneous concealment from one side and clear visualization from the other. This research opens intriguing possibilities for modern obscurant design and imaging systems through highly asymmetric and inhomogeneous particles besides target detection and identification capabilities in challenging environments.

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