高能电子束冲击实验用靶丝精确复位系统

张元; 钟兴; 徐振; 金光

doi:doi:10.3788/ope.20142210.2779

光学精密工程, 2014, 22 (10): 2779, 网络出版: 2014-11-06

高能电子束冲击实验用靶丝精确复位系统

Target filament accurate restoring system in high-energetic particle burst experiment

论文大纲

张元 ^*钟兴徐振金光

作者单位

中国科学院长春光学精密机械与物理研究所小卫星技术国家地方联合工程研究中心,吉林长春 130033

高能电子束冲击韧致辐射靶丝双目立体视觉复位系统 high-energtic particle burst bremsstrahlung target filament binocular stereovision restoring system

摘要

考虑高能电子束冲击实验中韧致辐射靶丝对精确复位的需求,设计了用于靶丝精确复位的辅助系统。首先,根据双目视觉原理推导了用于复位系统的重要公式;然后,根据实际使用的工况,设计了靶丝精确复位系统方案,包括硬件指标论证和软件算法设计。最后,在模拟真实工况环境下,搭建了实验平台,对系统的复位精度误差进行了测算。测试结果显示所研制的复位系统的复位精度误差为2%。半实物仿真实验结果显示,这套复位系统实现了高能电子束冲击实验中对韧致辐射靶丝的精确复位。由于研究对象是复位系统,而非定位系统,不需要进行标定,因此不存在标定误差,其研制成功保证了高能电子束冲击实验的可靠性。

Abstract

In consideration of the demand of bremsstrahlung conversion target filament for accurate restoring in high-energetic particle burst experiments,a service device for target filament accurate restoring was designed. First, some key formulas of restoring system were derived according to the stereoscopic theory. Then, a scheme for design of an accurate restoring system of the micro target filament was proposed according to the real application. Finally, an experiment platform to simulate real conditions was established to test the restoring accuracy error of this system. The experiment results indicate that the accuracy error of this restoring system is 2%.The semi-physical simulation experiment illustrates that this restoring system reaches the accurate restoring of the bremsstrahlung conversion target filament in the high-energetic particle burst experiments. As the research object is a restoring system rather than a positioning system, it do not need to be calibrated, so there is no calibration error. The target filament accurate restoring system developed ensures the reliability of high energy electron beam burst experiments.

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张元, 钟兴, 徐振, 金光. 高能电子束冲击实验用靶丝精确复位系统[J]. 光学精密工程, 2014, 22(10): 2779. ZHANG Yuan, ZHONG Xing, XU Zhen, JIN Guang. Target filament accurate restoring system in high-energetic particle burst experiment[J]. Optics and Precision Engineering, 2014, 22(10): 2779.

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