Simulations and Design of a Single-Photon CMOS Imaging Pixel Using Multiple Non-Destructive Signal Sampling

A single-photon CMOS image sensor (CIS) design based on pinned photodiode (PPD) with multiple charge transfers and sampling is described. In the proposed pixel architecture, the photogenerated signal is sampled non-destructively multiple times and the results are averaged. Each signal measurement is statistically independent and by averaging, the electronic readout noise is reduced to a level where single photons can be distinguished reliably. A pixel design using this method was simulated in TCAD and several layouts were generated for a 180-nm CMOS image sensor process. Using simulations, the noise performance of the pixel was determined as a function of the number of samples, sense node capacitance, sampling rate and transistor characteristics. The strengths and limitations of the proposed design are discussed in detail, including the trade-off between noise performance and readout rate and the impact of charge transfer inefficiency (CTI). The projected performance of our first prototype device indicates that single-photon imaging is within reach and could enable ground-breaking performances in many scientific and industrial imaging applications.

[1]  D. D. Wen,et al.  Design and operation of a floating gate amplifier , 1974 .

[2]  Shoji Kawahito,et al.  Effectiveness of a correlated multiple sampling differential averager for reducing 1/f noise , 2005, IEICE Electron. Express.

[3]  E. Garcia,et al.  Single-photon imaging. , 1995, Academic radiology.

[4]  Thomas Vogelsang,et al.  Reduction of CMOS Image Sensor Read Noise to Enable Photon Counting , 2016, Sensors.

[5]  James E. Gunn,et al.  New advancements in charge-coupled device technology: subelectron noise and 4096 x 4096 pixel CCDs , 1990, Other Conferences.

[6]  Andrew D. Holland,et al.  Determination of In Situ Trap Properties in CCDs Using a “Single-Trap Pumping” Technique , 2014, IEEE Transactions on Nuclear Science.

[7]  David Hall,et al.  Technology advancement of the CCD201-20 EMCCD for the WFIRST coronagraph instrument: sensor characterization and radiation damage , 2015, 1601.01761.

[8]  Konstantin D. Stefanov,et al.  Digital CDS for image sensors with dominant white and 1/f noise , 2015 .

[9]  Robert K. Henderson,et al.  A TCAD and Spectroscopy Study of Dark Count Mechanisms in Single-Photon Avalanche Diodes , 2013, IEEE Transactions on Electron Devices.

[10]  Craig Mackay High-Resolution Imaging in the Visible with Faint Reference Stars on Large Ground-Based Telescopes , 2019 .

[11]  Juan Estrada,et al.  Sub-electron readout noise in a Skipper CCD fabricated on high resistivity silicon , 2012 .

[12]  Laurens Korthout,et al.  Charge-Coupled CMOS TDI Imager , 2017 .

[13]  Shoji Kawahito,et al.  A 0.27e-rms Read Noise 220-μV/e-Conversion Gain Reset-Gate-Less CMOS Image Sensor With 0.11-μm CIS Process , 2015, IEEE Electron Device Letters.

[14]  Olivier Marcelot,et al.  Influence of Pixel Design on Charge Transfer Performances in CMOS Image Sensors , 2018, IEEE Transactions on Electron Devices.

[15]  Olivier Daigle The use ofEMCCDs as silicon-based photon counting devices , 2018, 2018 17th Workshop on Information Optics (WIO).

[16]  Matteo Porro,et al.  The DEPFET Sensor-Amplifier Structure: A Method to Beat 1/f Noise and Reach Sub-Electron Noise in Pixel Detectors , 2016, Sensors.

[17]  E. Fossum Modeling the Performance of Single-Bit and Multi-Bit Quanta Image Sensors , 2013, IEEE Journal of the Electron Devices Society.

[18]  John Tower,et al.  Particle and Photon Detection: Counting and Energy Measurement , 2016, Sensors.

[19]  Alex Drlica-Wagner,et al.  Single-Electron and Single-Photon Sensitivity with a Silicon Skipper CCD. , 2017, Physical review letters.

[20]  Donald B. Hondongwa,et al.  A Review of the Pinned Photodiode for CCD and CMOS Image Sensors , 2014, IEEE Journal of the Electron Devices Society.

[21]  E. Fossum,et al.  Quanta Image Sensor Jot With Sub 0.3e- r.m.s. Read Noise and Photon Counting Capability , 2015, IEEE Electron Device Letters.

[22]  James R. Janesick,et al.  Sub-electron noise charge-coupled devices , 1990, Other Conferences.

[23]  Edoardo Charbon,et al.  High-Performance Back-Illuminated Three-Dimensional Stacked Single-Photon Avalanche Diode Implemented in 45-nm CMOS Technology , 2018, IEEE Journal of Selected Topics in Quantum Electronics.

[24]  The use of EMCCDs as silicon-based photon counting devices 1 , 2018 .