Journal of Jilin University(Engineering and Technology Edition) ›› 2021, Vol. 51 ›› Issue (4): 1476-1481.doi: 10.13229/j.cnki.jdxbgxb20200398

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CMOS array imaging method of coordinated multichannel based on drift angle adjusting mechanism

Liu ZHANG(),Liang SHEN,Wen-hua WANG(),He LIU   

  1. College of Instrumentation & Electrical Engineering,Jilin University,Changchun 130012,China
  • Received:2020-06-08 Online:2021-07-01 Published:2021-07-14
  • Contact: Wen-hua WANG E-mail:zhangliu@jlu.edu.cn;wangwh900@jlu.edu.cn

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Abstract:

Although the existing method of rotation of each sensor can improve the matching accuracy of the drift angle,it results in the discontinuity of the image synthesized by the detector with optical butting on the focal plane. In order to solve the above problems, an electronic imaging system based on CMOS image sensor GMAX3265 and FPGA is designed. The system uses the windowing mode of CMOS image sensor to Real-time clipping the nonlinear part of the image synthesized by adjacent detectors, thus forming a continuous image strip. Firstly, the difference between the traditional drift angle compensation method and the slice rotation drift angle compensation method is compared and analyzed when the detector adopts optical butting. Secondly, the number of cutting rows is calculated and the cutting precision is analyzed. Finally, the electronic system is completed through the overall system design and driving timing design. The experimental results show that when the rotation angle difference between adjacent detectors is 0.1 °, the ratio of error pixels to total pixels is 0.1165%, which does not lose too much image and improves image continuity.

Key words: rotation of each sensor, optical butting, discontinuity, CMOS image sensor, windowing

CLC Number: 

  • V443.5

Fig.1

Image generated by traditional method of adjusting drift angle"

Fig.2

Image generated by new method of adjusting drift angle"

Fig.3

Geometric relationship of adjacent detectors"

Table 1

Accuracy of the CORDIC algorithm"

输入值

/(°)

sinθcosθ
FPGA仿真值MATLAB计算值误差值FPGA仿真值MATLAB计算值误差值
0.50.999 962 3300.999 961 9234.067 98e-070.008 666 9920.008 726 5355.954 31e-05
10.999 847 4120.999 847 6952.830 39e-070.017 455 1010.017 452 4072.694 10e-06
1.50.999 658 5850.999 657 3251.259 62e-060.026 119 9470.026 176 9495.700 11e-05
20.999 390 6020.999 390 8272.249 09e-070.034 904 9570.034 899 4975.460 15e-06
2.50.999 050 3790.999 048 2222.157 20e-060.043 565 2730.043 619 3875.411 38e-05
30.998 628 8550.998 629 5356.799 80e-070.052 344 3220.052 335 9578.365 52e-06
3.50.998 137 7120.998 134 7982.914 07e-060.060 997 2480.061 048 5405.129 20e-05

Fig.4

System architecture diagram"

Fig.5

Driving timing for SPI"

Fig.6

Driving timing for algorithm of CORDIC"

Fig.7

Mosaic image before windowing"

Fig.8

Mosaic image after windowing"

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