Lidar Waveform-Based Analysis of Depth Images Constructed Using Sparse Single-Photon Data

Altmann, Yoann; Ren, Ximing; McCarthy, Aongus; Buller, Gerald S.; McLaughlin, Stephen

doi:10.1109/tip.2016.2526784

Cited by 139 publications

(161 citation statements)

References 26 publications

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“…This is not a low number of photons per pixel comparable to recent works in which deconvolution is not needed, [14][15][16][17] but the results suggest that it is low enough that our explicit Poissonian modeling of observed photon counts improves performance. The flattened photon data cube f (Y) ∈ N nxny×nt is illustrated in image form in Fig.…”

Section: Simulationsmentioning

confidence: 45%

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Photon-efficient super-resolution laser radar

Shin

Shapiro

Goyal

2017

Wavelets and Sparsity XVII

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The resolution achieved in photon-efficient active optical range imaging systems can be low due to non-idealities such as propagation through a diffuse scattering medium. We propose a constrained optimization-based framework to address extremes in scarcity of photons and blurring by a forward imaging kernel. We provide two algorithms for the resulting inverse problem: a greedy algorithm, inspired by sparse pursuit algorithms; and a convex optimization heuristic that incorporates image total variation regularization. We demonstrate that our framework outperforms existing deconvolution imaging techniques in terms of peak signal-to-noise ratio. Since our proposed method is able to super-resolve depth features using small numbers of photon counts, it can be useful for observing fine-scale phenomena in remote sensing through a scattering medium and through-the-skin biomedical imaging applications.

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Section: Simulationsmentioning

confidence: 45%

“…Markov random field models, 14 and convex optimization. [15][16][17] One core assumption behind these existing lowlight depth imaging frameworks is that the spatial spot size of the illumination is small enough that we can assume that each pixel measurement has addressed a different scene patch.…”

mentioning

confidence: 99%

Photon-efficient super-resolution laser radar

Shin

Shapiro

Goyal

2017

Wavelets and Sparsity XVII

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“…According to [6], [14], each photon count y i,j, ,t is assumed to be drawn from the following Poisson distribution…”

Section: Observation Modelmentioning

confidence: 99%

“…However, a potential drawback of single photon counting is that the integration times required for accurate depth measurement can be too long for rapid depth profiling. Even with single-detector scanning systems, significant reductions in acquisition time have been demonstrated by application of advanced computational imaging approaches, such as first-photon imaging [5] or single-photon data analysis in the extremely photon-starved regime [6], [7], which have allowed depth images to be reconstructed with very few photon returns.…”

Section: Introductionmentioning

confidence: 99%

Bayesian restoration of reflectivity and range profiles from subsampled single-photon multispectral Lidar data

Altmann

Tobin

Maccarone

et al. 2017

2017 25th European Signal Processing Conference (EUSIPCO)

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Abstract-In this paper, we investigate the recovery of range and spectral profiles associated with remote three-dimensional scenes sensed via single-photon multispectral Lidar (MSL). We consider different spatial/spectral sampling strategies and compare their performance for similar overall numbers of detected photons. For a regular spatial grid, the first strategy consists of sampling all the spatial locations of the grid for each of the wavelengths. Conversely, the three other strategies consist, for each spatial location, of acquiring a reduced number of wavelengths, chosen randomly or in a deterministic manner. We propose a fully automated computational method, adapted for the different sampling strategies in order to recover the target range profile, as well as the reflectivity profiles associated with the different wavelengths. The performance of the four sampling strategies is illustrated using a single photon MSL system with four wavelengths. The results presented demonstrate that although the first strategy usually provides more accurate results, the subsampling strategies do not exhibit a significant performance degradation, particularly for extremely photonstarved data (down to one photon per pixel on average).

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“…Very recently, computational imaging frameworks have been introduced to process photon detection data without treating a detection-time histogram as approximating a flux waveform, and using regularization predicated on piecewise smoothness in the transverse dimensions [6][7][8][9][10]. For natural scenes, accurate results have been demonstrated from as little as 1 detected photon per pixel, even in the presence of significant ambient light.…”

Section: Introductionmentioning

confidence: 99%

Computational single-photon depth imaging without transverse regularization

Shin

Shapiro

Goyal

2016

2016 IEEE International Conference on Image Processing (ICIP)

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Depth profile reconstruction of a scene at low light levels using an active imaging setup has wide-ranging applications in remote sensing. In such low-light imaging scenarios, single-photon detectors are employed to time-resolve individual photon detections. However, even with single-photon detectors, current frameworks are limited to using hundreds of photon detections at each pixel to mitigate Poisson noise inherent in light detection. In this paper, we discuss two pixelwise imaging frameworks that allow accurate reconstruction of depth profiles using small numbers of photon detections. The first framework addresses the problem of depth reconstruction of an opaque target, in which it is assumed that each pixel contains exactly one reflector. The second framework addresses the problem of reconstructing multiple-depth pixels. In each scenario, our framework achieves photon efficiency by combining accurate statistics for individual photon detections with a longitudinal sparsity constraint tailored to the imaging problem. We demonstrate the photon efficiencies of our frameworks by comparing them with conventional imagers that use more naïve models based on high light-level assumptions.

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Lidar Waveform-Based Analysis of Depth Images Constructed Using Sparse Single-Photon Data

Cited by 139 publications

References 26 publications

Photon-efficient super-resolution laser radar

Photon-efficient super-resolution laser radar

Bayesian restoration of reflectivity and range profiles from subsampled single-photon multispectral Lidar data

Computational single-photon depth imaging without transverse regularization

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