Abstract
This paper presents a temporal noise analysis of charge-domain sampling readout circuits for Complementary Metal-Oxide Semiconductor (CMOS) image sensors. In order to address the trade-off between the low input-referred noise and high dynamic range, a Gm-cell-based pixel together with a charge-domain correlated-double sampling (CDS) technique has been proposed to provide a way to efficiently embed a tunable conversion gain along the read-out path. Such readout topology, however, operates in a non-stationery large-signal behavior, and the statistical properties of its temporal noise are a function of time. Conventional noise analysis methods for CMOS image sensors are based on steady-state signal models, and therefore cannot be readily applied for Gm-cell-based pixels. In this paper, we develop analysis models for both thermal noise and flicker noise in Gm-cell-based pixels by employing the time-domain linear analysis approach and the non-stationary noise analysis theory, which help to quantitatively evaluate the temporal noise characteristic of Gm-cell-based pixels. Both models were numerically computed in MATLAB using design parameters of a prototype chip, and compared with both simulation and experimental results. The good agreement between the theoretical and measurement results verifies the effectiveness of the proposed noise analysis models.
Highlights
Advanced imaging systems for high-end applications, such as scientific and medical imaging, demand high-sensitivity Complementary Metal-Oxide Semiconductor (CMOS) image sensors (CIS)
A charge-domain sampling pixel readout circuit based on trans-conductance (Gm)-cells has been proposed in [12,13] as an alternative to the conventional voltage-domain implementation based on source followers (SF)
A charge-domain sampling pixel readout circuit based on trans(Gm)-cells has been proposed in [12,13] as andetails alternative theGm-cell-based conventional voltageWhile theconductance operational principle and implementation of tothe pixel have been on source followers (SF)
Summary
Advanced imaging systems for high-end applications, such as scientific and medical imaging, demand high-sensitivity CMOS image sensors (CIS). The use of a fixed high-gain amplification in the pixel, either in the charge domain or the voltage domain, inevitably leads to degradation of the dynamic range (DR), resulting in undesired contrast loss in the final image To solve this problem, a charge-domain sampling pixel readout circuit based on trans-conductance (Gm)-cells has been proposed in [12,13] as an alternative to the conventional voltage-domain implementation based on source followers (SF). Thedomain proposed structure is able toleads overcome the trade-off between resulting in undesired contrast loss in the final image To solve this problem, a charge-domain sampling pixel readout circuit based on trans(Gm)-cells has been proposed in [12,13] as andetails alternative theGm-cell-based conventional voltageWhile theconductance operational principle and implementation of tothe pixel have been on source followers (SF).
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