Temporal Readout Noise Analysis and Reduction Techniques for Low-Light CMOS Image Sensors

In this paper, an analytical noise calculation is presented to derive the impact of process and design parameters on 1/f and thermal noise for a low-noise CMOS image sensor (CIS) readout chain. It is shown that dramatic noise reduction is obtained by using a thin-oxide transistor as the source follower of a typical 4T pixel. This approach is confirmed by a test chip designed in a 180-nm CIS process and embedding small arrays of the proposed new pixels together with state-ofthe- art 4T pixels for comparison. The new pixels feature a pitch of 7.5 mu m and a fill factor of 66%. A 0.4e-rms input-referred noise and a 185-mu V/e-conversion gain are obtained. Compared with state-of-the-art pixels, also present onto the test chip, the rms noise is divided by more than 2 and the conversion gain is multiplied by 2.2.

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Temporal Readout Noise Analysis and Reduction Techniques for Low-Light CMOS Image Sensors

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A 500 x 500 Dual-Gate SPAD Imager With 100% Temporal Aperture and 1 ns Minimum Gate Length for FLIM and Phasor Imaging Applications

reference data for "A Critical Comparison of Annual Glare Simulation Methods"

reference data for "A Critical Comparison of Annual Glare Simulation Methods"

A 500 x 500 Dual-Gate SPAD Imager With 100% Temporal Aperture and 1 ns Minimum Gate Length for FLIM and Phasor Imaging Applications