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Manuscript ID : 678652 Visit : 163 Page: 21 - 28

20.1001.1.29809231.1399.9.35.1.8

Article Type: Original Research

Optimization of low power 12-bit cycle analog to digital converter and its application in CMOS image sensor

Subject Areas : Electronics Engineering

Asghar Ebrahimi 1 , Mina Shirali 2

1 - Islamic Azad University, Faculty member
2 - Islamic Azad University, Bushehr Branch, Department of Electronics, Bushehr, Iran

Received: 2020-12-25 Accepted : 2020-12-25 Published : 2020-04-20

Keywords:

Abstract :

In this paper, the performance of high-speed video cameras using CMOS video sensor technology has been improved. A high-speed CMOS video sensor with parallel analog output of 1000 frames per second at 512 x 512 pixels and 3000 frames per second at 1024 x 1024 pixels For high-amplitude CMOS image sensors, a pixel ADC of a sequential column-parallel approximation ADC has been reported. High-speed, 12-bit columnar-parallel ADC arrays with a small 0.09 array size are included on either side of the image array. A method for accelerating conversion speeds using variable clock synchronization and sampling capacitors has been developed. Is. The pixel load amplifier achieves a light sensitivity of 19.9 V / lxs. The full signal size at the pixel output is 1.8V in the power supply 3.3V and the noise level is measured at 1.8 and the dynamic signal amplitude is 60dB.

References:

[1] D. X. Yang, A. E. Gamal, B. Fowler, and H. Tian, “A 640x512 CMOSImage Sensor with Ultra Wide Dynamic Range Floating-Point Pixel-LevelADC,” ISSCC Dig. Tech. Papers, pp. 308-309, Feb., 2002.

[2] W. Bidermann, A. E. Gamal, S. Ewedemi, J. Reyneti, H. Tian, D. Wile,D. Yang, “A 0.18m High Dynamic Range NTSC/PAL Imaging System-ona-Chip with Enhanced DRAM Frame Buffer,” ISSCC Dig. Tech. Papers, pp.212-213, Feb., 2007.

[3] O.Y. Pecht, A. Belenky, “Autoscaling CMOS APS with CustomizedIncrease of Dynamic Range,” ISSCC Dig. Tech. Papers, pp. 100-101, Feb.,2008.

[4] Steven Decker, R. Daniel McGrath, Kevin Brehmer, Gharles G. Sodini,“A 256 x 256 CMOS Imaging Array with Wide Dynamic Range Pixels andColumn-Parallel Digital Ouput”, IEEE J. Solid-State Circuits, 33, no. 12,pp. 2081-2091, 2009.

[5] S. H. Lewis and P.R.Gray, “A Pipelined 5-MSample/s 9-bit Analog-to-Digital Converter,’’ IEEE J. Solid-State Circuits, pp. 954-961, vol. SC-22,2010

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[1] D. X. Yang, A. E. Gamal, B. Fowler, and H. Tian, “A 640x512 CMOSImage Sensor with Ultra Wide Dynamic Range Floating-Point Pixel-LevelADC,” ISSCC Dig. Tech. Papers, pp. 308-309, Feb., 2002.

[2] W. Bidermann, A. E. Gamal, S. Ewedemi, J. Reyneti, H. Tian, D. Wile,D. Yang, “A 0.18m High Dynamic Range NTSC/PAL Imaging System-ona-Chip with Enhanced DRAM Frame Buffer,” ISSCC Dig. Tech. Papers, pp.212-213, Feb., 2007.

[3] O.Y. Pecht, A. Belenky, “Autoscaling CMOS APS with CustomizedIncrease of Dynamic Range,” ISSCC Dig. Tech. Papers, pp. 100-101, Feb.,2008.

[4] Steven Decker, R. Daniel McGrath, Kevin Brehmer, Gharles G. Sodini,“A 256 x 256 CMOS Imaging Array with Wide Dynamic Range Pixels andColumn-Parallel Digital Ouput”, IEEE J. Solid-State Circuits, 33, no. 12,pp. 2081-2091, 2009.

[5] S. H. Lewis and P.R.Gray, “A Pipelined 5-MSample/s 9-bit Analog-to-Digital Converter,’’ IEEE J. Solid-State Circuits, pp. 954-961, vol. SC-22,2010

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