A single-photon sampling architecture for solid-state imaging

TL;DR

This paper introduces a novel single-photon sampling architecture for solid-state imaging that efficiently uses group testing principles to reduce TDCs, enabling high-resolution, low-power photon detection suitable for applications like LiDAR and PET.

Contribution

It proposes a multiplexing-based architecture leveraging group testing for efficient, low-cost, and high-resolution photon detection in solid-state sensors, with explicit bounds and optimized matrices.

Findings

Achieved 98.6% photon recovery in PET simulations.

Used only 161 TDCs for a 120x120 sensor with 40ps resolution.

Guaranteed unique decoding of up to 4 simultaneous photons.

Abstract

Advances in solid-state technology have enabled the development of silicon photomultiplier sensor arrays capable of sensing individual photons. Combined with high-frequency time-to-digital converters (TDCs), this technology opens up the prospect of sensors capable of recording with high accuracy both the time and location of each detected photon. Such a capability could lead to significant improvements in imaging accuracy, especially for applications operating with low photon fluxes such as LiDAR and positron emission tomography. The demands placed on on-chip readout circuitry imposes stringent trade-offs between fill factor and spatio-temporal resolution, causing many contemporary designs to severely underutilize the technology's full potential. Concentrating on the low photon flux setting, this paper leverages results from group testing and proposes an architecture for a highly efficient readout of pixels using only a small number of TDCs, thereby also reducing both cost and power consumption. The design relies on a multiplexing technique based on binary interconnection matrices. We provide optimized instances of these matrices for various sensor parameters and give explicit upper and lower bounds on the number of TDCs required to uniquely decode a given maximum number of simultaneous photon arrivals. To illustrate the strength of the proposed architecture, we note a typical digitization result of a 120x120 photodiode sensor on a 30um x 30um pitch with a 40ps time resolution and an estimated fill factor of approximately 70%, using only 161 TDCs. The design guarantees registration and unique recovery of up to 4 simultaneous photon arrivals using a fast decoding algorithm. In a series of realistic simulations of scintillation events in clinical positron emission tomography the design was able to recover the spatio-temporal location of 98.6% of all photons that caused pixel firings.