Signal-to-noise properties of correlation plenoptic imaging with chaotic light

Scala, Giovanni; D’Angelo, Milena; Garuccio, Augusto; Pascazio, Saverio; Pepe, F.

doi:10.1103/physreva.99.053808

Cited by 28 publications

(30 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A different approach to the singular value decomposition might solve the stability issue of PGI, confirming what has been observed in the literature [21]. Theoretical analysis reported in several papers (e. g. [36], [37]) predicts that the SNR proportionally increases with the square root of the number of frames. To check whether this applies to our results, we fitted the SNR curves with a function of the type f (x) = Ax 0.5 + B (see the exemplary fit in Fig.…”

Section: B Signal-to-noise Ratio (Snr) Analysissupporting

confidence: 83%

“…[31], where the authors use a source with a wide spectral range in combination with a spectrometer to acquire multiple images at once. Different setups to realize the scheme have been compared in [32], one of them is depicted in Fig. 2.…”

Section: B Correlation Plenoptic Imagingmentioning

confidence: 99%

“…If z A = z B the target is in focus and Detector D A images the speckle field in the object plane. Any plane for which the focusing condition is not fulfilled can be refocused in post processing using the following, refocusing equation [10], [32]:…”

Section: B Correlation Plenoptic Imagingmentioning

confidence: 99%

See 2 more Smart Citations

Classical Ghost Imaging: A Comparative Study of Algorithmic Performances for Image Reconstruction in Prospect of Plenoptic Imaging

et al. 2021

View full text Add to dashboard Cite

Ghost Imaging has been extensively explored for 25 years for a two reasons: the rich physics of second-order photon correlations that enable this imaging scheme and the possibility of implementing new imaging protocols with interesting real-life applications, e.g. imaging in turbulent media, investigation of sensitive samples in low-flux regimes, 3-D plenoptic imaging, and so on. Since the first demonstration of Ghost Imaging, several extended versions of the Traditional Ghost Imaging algorithm have been proposed, such as Correspondence Ghost Imaging, Pseudo-Inverse Ghost Imaging, and normalization techniques that rely on different computational approaches to obtain the image from measured data. So far, a direct comparison of all above-mentioned protocols for the same experimental parameters is still lacking. In this work, we experimentally and numerically implement a number of different methods and systematically compare them in terms of the obtained SNR and computational cost. Furthermore, we investigate their compatibility with Correlation Plenoptic Imaging, a technique strictly connected to Ghost Imaging, that allows refocusing of images, increasing the depth of field (DOF) and making 3D visualization possible. Our results can provide useful guidelines for the choice of a suitable numerical algorithm for in the light of Ghost Imaging applications.

show abstract

Section: B Signal-to-noise Ratio (Snr) Analysissupporting

confidence: 83%

Section: B Correlation Plenoptic Imagingmentioning

confidence: 99%

See 1 more Smart Citation

Classical Ghost Imaging: A Comparative Study of Algorithmic Performances for Image Reconstruction in Prospect of Plenoptic Imaging

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Interestingly, recent studies have shown that, in the case of chaotic light illumination, the plenoptic properties of the correlation function do not need to rely strictly on ghost imaging: correlations can be measured between any two planes where ordinary images (see Figure 1b) are formed [35]. This discovery has led to the intriguing result that the SNR of CPI improves when ghost imaging of the object is replaced by standard imaging [40]. In particular, excellent noise performances are expected in the case of images of birefringent objects placed between crossed polarizers.…”

Section: Plenoptic Imaging With Correlations: From Working Principle To Recent Advancesmentioning

confidence: 99%

“…The accuracy of the correlation function estimate (4) increases with the number of frames like N f [40]. However, increasing N f also linearly extends the total acquisition time T. Therefore, the combination of (1) fast and low-noise sensors, (2) methods to extract a good quality signal from smaller number of frames, and (3) tools for efficient data transfer and elaboration, is crucial in order to speed-up the acquisition process and make the CPI technology ready for real-world applications.…”

mentioning

confidence: 99%

Towards Quantum 3D Imaging Devices

et al. 2021

Self Cite

View full text Add to dashboard Cite

We review the advancement of the research toward the design and implementation of quantum plenoptic cameras, radically novel 3D imaging devices that exploit both momentum–position entanglement and photon–number correlations to provide the typical refocusing and ultra-fast, scanning-free, 3D imaging capability of plenoptic devices, along with dramatically enhanced performances, unattainable in standard plenoptic cameras: diffraction-limited resolution, large depth of focus, and ultra-low noise. To further increase the volumetric resolution beyond the Rayleigh diffraction limit, and achieve the quantum limit, we are also developing dedicated protocols based on quantum Fisher information. However, for the quantum advantages of the proposed devices to be effective and appealing to end-users, two main challenges need to be tackled. First, due to the large number of frames required for correlation measurements to provide an acceptable signal-to-noise ratio, quantum plenoptic imaging (QPI) would require, if implemented with commercially available high-resolution cameras, acquisition times ranging from tens of seconds to a few minutes. Second, the elaboration of this large amount of data, in order to retrieve 3D images or refocusing 2D images, requires high-performance and time-consuming computation. To address these challenges, we are developing high-resolution single-photon avalanche photodiode (SPAD) arrays and high-performance low-level programming of ultra-fast electronics, combined with compressive sensing and quantum tomography algorithms, with the aim to reduce both the acquisition and the elaboration time by two orders of magnitude. Routes toward exploitation of the QPI devices will also be discussed.

show abstract