A 256 × 256 CMOS image sensor with differential readout and data converter circuits

Karamzadeh, Khadijeh; Teymouri, Masood; Dousti, Massoud; Torkzadeh, Pooya

doi:10.1002/cta.3580

Circuit Theory & Apps

2023

DOI: 10.1002/cta.3580

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A 256 × 256 CMOS image sensor with differential readout and data converter circuits

Khadijeh Karamzadeh

Masood Teymouri

Massoud Dousti

et al.

Abstract: Summary In this paper, a 256 × 256 CMOS image sensor is introduced in which the pixel signals are read and converted into digital data in a completely differential mode. This technique helps to obtain pixel signals with higher linearity and accuracy compared with conventional methods. Improving the linearity and accuracy of the image sensor has a direct impact on increasing the quality of the generated images. The simulation results of the proposed pixel readout circuit show that the THD, SINAD, SNR, and SFDR … Show more

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2024

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Cited by 2 publications

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A 2.72 μs row conversion time 11‐bit column‐parallel single‐slope analog to digital converter with differential‐clocks‐assisted time to digital converter interpolation for complementary metal oxide semiconductors image sensor

Duan,

Nie,

2024

Circuit Theory & Apps

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This paper presents an innovative readout scheme that utilizes a pair of differential‐clocks‐assisted time‐to‐digital converter (DCA‐TDC) in CMOS image sensors (CISs). The DCA‐TDC utilizes only half the number of ordinary TDC delay chain units by employing a binary‐weighted search algorithm to determine the most significant bit (MSB) for fine quantization of a single‐slope analog‐to‐digital converter (SS ADC). Additionally, the layout area and dynamic power introduced by the improved DCA‐TDC delay chain are halved compared to an ordinary TDC delay chain. The proposed SS ADC is designed and simulated using the 0.11 m standard CMOS proces, achieving an 11‐bit ADC with a column‐level power consumption of 65.4 W, and a row conversion time of 2.72 s, within a design environment featuring an analog voltage of 3.3 V, a digital voltage of 1.5 V, a clock frequency of 62.5 MHz, and a temporal resolution of 500 ps. Furthermore, this design achieves an effective number of bits (ENOB) of 10.71 and a figure of merit (FoM) of 110.5 fJ/step. By interpolating a DCA‐TDC, the quantization speed is enhanced compared to traditional SS ADCs, presenting an effective solution for high‐frame‐rate CIS implementations.

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A 2.72 μs row conversion time 11‐bit column‐parallel single‐slope analog to digital converter with differential‐clocks‐assisted time to digital converter interpolation for complementary metal oxide semiconductors image sensor

Duan,

Nie,

2024

Circuit Theory & Apps

View full text Add to dashboard Cite

show abstract

Single‐Shot Auto‐Exposure and High Dynamic Range Imaging Based on Asynchronous Operation of Pixel Array Circuitry

Lamouaraa‐Sedlackova,

Fernández‐Berni,

Carmona‐Galán

2024

Circuit Theory & Apps

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This paper introduces an image formation technique that realizes automatic adaptation to the illumination conditions during image capture. This adaptation takes place asynchronously in a single shot, requiring neither external control nor iterations on the exposure setting. These characteristics are especially suitable for applications such as visual robot navigation, where illumination may abruptly change and immediate decisions must be made. The equations that model the proposed technique show exposure‐time independence. Moreover, each pixel adapts itself according to the ratio between local and global illuminations. The dependence on this ratio—which is a relative rather than absolute magnitude—along with the aforementioned independence on exposure time means that, theoretically, any illumination scenario can be represented within an arbitrary signal range. We also address the CMOS implementation of this technique. An extensive set of electrical simulations confirms its auto‐exposure and high‐dynamic‐range encoding capabilities. In particular, we simulated the capture of a 118‐dB scene on a ‐px array over five orders of magnitude of ambient illumination. Corner and mismatch simulations reveal strong robustness of the proposed circuitry against fabrication non‐idealities. Finally, although we aim to applications in which large image resolution is not a critical specification, strategies to minimize the impact of the required focal‐plane circuit elements on the pixel pitch are examined.

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A 256 × 256 CMOS image sensor with differential readout and data converter circuits

Cited by 2 publications

References 29 publications

A 2.72 μs row conversion time 11‐bit column‐parallel single‐slope analog to digital converter with differential‐clocks‐assisted time to digital converter interpolation for complementary metal oxide semiconductors image sensor

A 2.72 μs row conversion time 11‐bit column‐parallel single‐slope analog to digital converter with differential‐clocks‐assisted time to digital converter interpolation for complementary metal oxide semiconductors image sensor

Single‐Shot Auto‐Exposure and High Dynamic Range Imaging Based on Asynchronous Operation of Pixel Array Circuitry

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