Litcius/Paper detail

A 32 × 32-Pixel CMOS Imager for Quantum Optics With Per-SPAD TDC, 19.48% Fill-Factor in a 44.64-μm Pitch Reaching 1-MHz Observation Rate

Majid Zarghami, Leonardo Gasparini, Luca Parmesan, Manuel Moreno-García, André Stefanov, Bänz Bessire, Manuel Unternährer, Matteo Perenzoni

2020IEEE Journal of Solid-State Circuits52 citationsDOI

Abstract

This article reports the design and characterization of a 32 × 32 single-photon avalanche diode (SPAD) time-resolved image sensor for quantum imaging applications fabricated in a 150-nm CMOS standard technology. A per-SPAD time-to-digital converter (TDC) records the spatial cross correlation functions of a flux of entangled photons. Each 44.64-μm pixel with 19.48% fill-factor features a 210.2-ps resolution, 50-ns (8-bit) range TDC with 1.28-LSB differential and 1.92-LSB integral nonlinearity (DNL/INL). The sensor achieves an observation rate of up to 1 MHz through a current-based mechanism that avoids reading empty frames when the photon rates are low. A row-skipping mechanism detects the absence of SPAD activity in a row to increase the duty cycle. These two features require only three transistors in each pixel. The sensor functionality is demonstrated in a quantum imaging experiment that achieves super-resolution.

Topics & Concepts

PhysicsPixelImage sensorOpticsDuty cycleDifferential nonlinearityDiodeCMOSPhotonImage resolutionOptoelectronicsVoltageQuantum mechanicsAdvanced Optical Sensing TechnologiesAdvanced Fluorescence Microscopy TechniquesOcular and Laser Science Research