Design and validation of calibration between tube focus spot and center plane of rotation in computed tomography system_Journal of Biomedical Engineering

Authors：

 YU Xiaomin ¹ , YIN Wei ² , LAN Yu ¹ , LIU Zhihong ¹

1. Key Laboratory of Biomedical Effect of Physical Field and Instrument, School of Electrical and Electronic Engineering, Chengdu University of Information Technology, Chengdu 610225, P.R.China;
2. Chengdu Normal University, Chengdu 611130, P.R.China;

Corresponding author：

YU Xiaomin, Email: jonahyxm@126.com

Keywords：

calibration; tube focus spot; collimator; center plane of rotation

DOI：

10.7507/1001-5515.201812016

Video：

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Abstract Full text Figures/Tables Video References Cited by

This study proposed a method to calibrate tube focus spot and the center plane of rotation in computed tomography system. In the method, the tube was rotated to 0° and 180° respectively, and then one metal jig with symmetric windows A and B was scanned at each position under the tube cool and static condition. According to the geometry of tube focus spot, aperture center of the collimator and jig, the distance between tube focus spot and the center plane of rotation were calculated with the X ray transmittance data after denoising, mean value and normalization. To verify the practicability and validity of the method, the tube focus spot in a 16 slices CT system (Brivo CT385, GE, China) was calibrated, and the result after calibration was validated by scanning a polaroid film. The validation result showed that the deviation between tube focal spot and center plane of rotation was 0.02 mm and was in the error range within ± 0.1 mm. The results of this study showed that, as a simple and low-cost design, the method could be used for fast calibration between tube focus spot and the center plane of rotation.

Citation： YU Xiaomin, YIN Wei, LAN Yu, LIU Zhihong. Design and validation of calibration between tube focus spot and center plane of rotation in computed tomography system. Journal of Biomedical Engineering, 2019, 36(4): 664-669. doi: 10.7507/1001-5515.201812016 Copy

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1. 包尚联. 现代医学影像物理学. 北京: 北京大学医学出版社, 2003: 54-62.
2. 马继明, 张建奇, 宋顾周, 等. 全变分约束迭代滤波反投影CT重建. 光学学报, 2015, 35(2): 392-398.
3. Hounsfield G N. Computerized transverse axial scanning (tomography): part 1. description of system. British Journal of Radiology, 1973, 46(552): 1006-1022.
4. Zhang Hongyu, Li Yingxin, et al. The analysis of effective radiation dose during PET/CT examination. Chinese Journal of Biomedical Engineering, 2016, 25(3): 134-138.
5. Sodickson A, Baeyens P F, Andriole K P, et al. Recurrent CT, cumulative radiation exposure, and associated radiation-induced cancer risks from CT of adults. Radiology, 2009, 251(1): 175-184.
6. 余小敏, 姜添浩, 刘志宏, 等. 数字X射线摄影系统中探测器纵向自动追踪射线设计. 生物医学工程学杂志, 2018, 35(2): 297-300.
7. Mansoor A, Bagci U, Foster B, et al. Segmentation and image analysis of abnormal lungs at CT: current approaches, challenges, and future trends. Radiographics, 2015, 35(4): 1056-1076.
8. Shen Shiwen, Bui A A T, Cong J, et al. An automated lung segmentation approach using bidirectional chain codes to improve nodule detection accuracy. Comput Biol Med, 2015, 57: 139-149.
9. Jiang H. 计算机断层成像技术原理, 设计, 伪像和进展. 北京: 科学出版社, 2006: 106-116.
10. Sensakovic W, Starkey A, Armato S. A general method for the identification and repair of concavities in segmental medical images//IEEE Nuclear Science Symposium Conference Record Nuclear Science Symposium. Dresden: IEEE, 2008, 20(7): 5320-5326.
11. Sanchez-Fernadez M, de-Prado-Cumplido M, Arenas-Garcia J A. SVM multiregression for nonlinear channel estimation in multiple-input multiple-output systems. IEEE Transactions on Signal Processing, 2004, 52(8): 2298-2307.
12. Kitamura Y. Medical electrical equipment-part 2-44. Particular requirement for the basic safety and essential performance of X-ray equipment for computed tomography, IEC 60601-2-44: Ed 3, 2009: 30-35.

Journal of Biomedical Engineering

Design and validation of calibration between tube focus spot and center plane of rotation in computed tomography system

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