Performance assessment of SPAD arrays for coincidence detection in quantum-enhanced imaging

Single-Photon Avalanche-Diode (SPAD) arrays find extensive use in quantum imaging techniques that exploit entangledphotons states to overcome sensitivity limitations of classical imaging. Thanks to their compactness, low-voltage operation, single-photon sensitivity, absence of readout noise, and high frame-rate, SPAD arrays are particularly suited to detect temporally correlated photons over a scattered background. This work presents a scheme useful to model a generic quantum imaging measurement set-up, with its losses and non-idealities, and it provides the resulting calculations of pair rate (in case of quantum states made of two photons) and spurious single-photon rate at detector level. The computed rates are used to evaluate the performance in terms of signal-to-noise ratio of a possible SPAD array architecture based on an onchip photon coincidences detection, followed by an event-driven readout, which transfers only the addresses of those pixels involved in the coincidence event. Although bringing plenty of advantages in terms of power consumption, data storage, and readout time, especially as the pixels number increases, the intrinsic non-ideal operation timings of this architecture are linked to three possible cases of wrong detection. A detailed computation of these error probabilities is provided, together with a discussion about which design parameters most influence the detected signal quality. Since every on-chip coincidence detection and event-driven architecture is characterized by those same finite operation timings, the presented computation method can be considered a useful tool to optimize the design of detection systems used in quantum imaging and microscopy framework.

[1]  Ivano Ruo-Berchera,et al.  Quantum imaging with sub-Poissonian light: challenges and perspectives in optical metrology , 2019, Metrologia.

[2]  Valerio Pruneri,et al.  Quantum imaging for enhanced microscopy and light modulation , 2019, NanoScience + Engineering.

[3]  Federica A. Villa,et al.  Single Photon Avalanche Diode Arrays for Time-Resolved Raman Spectroscopy , 2021, Sensors.

[4]  F. Zappa,et al.  Single Photon Avalanche Diode Arrays for Quantum Imaging and Microscopy , 2021, Advanced Quantum Technologies.

[5]  S. Walborn,et al.  Spatial correlations in parametric down-conversion , 2010, 1010.1236.

[6]  Alberto Tosi,et al.  Planar CMOS analog SiPMs: design, modeling, and characterization , 2015 .

[7]  E. Charbon,et al.  Quantum correlation measurement with single photon avalanche diode arrays. , 2019, Optics express.

[8]  David Stoppa,et al.  Coincidence detection of spatially correlated photon pairs with a monolithic time-resolving detector array. , 2016, Optics express.

[9]  A. Tosi,et al.  Single-Photon Avalanche Diodes in a 0.16 μm BCD Technology With Sharp Timing Response and Red-Enhanced Sensitivity , 2018, IEEE Journal of Selected Topics in Quantum Electronics.

[10]  D. Faccio,et al.  Imaging and certifying high-dimensional entanglement with a single-photon avalanche diode camera , 2020, npj Quantum Information.

[11]  Matteo Perenzoni,et al.  A 32×32-pixel time-resolved single-photon image sensor with 44.64μm pitch and 19.48% fill-factor with on-chip row/frame skipping features reaching 800kHz observation rate for quantum physics applications , 2018, 2018 IEEE International Solid - State Circuits Conference - (ISSCC).