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基于双目视觉的飞行目标落地速度测量方法研究 被引量:5

Study on measuring approach of flying target landing parameters based on binocular vision model
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摘要 为了测量飞行目标落地速度,采用放置在落弹点区域附近的凝视等待式双目视觉摄像机,高速摄影交汇测量飞行目标的落地速度。根据不同时刻质心的空间三维坐标,用最小二乘法对目标航迹进行拟合,建立了目标三维空间轨迹的多项式函数,对多项式函数求导得到目标的飞行速度。实验与理论分析表明:采用的速度测量方法测量误差小于2%,测量方法正确、可靠,为飞行目标的速度测量提供了一条新的便捷可靠的途径。 In order to measure the landing speed, the binocular intersection measuring system is set up near the landing area to detect the landing parameters of flying target by high-speed photograph. The polynomial function of target track 3D curve is fitted with the method of least square according to the 3D coordinate of centroid at the different moments, so the flying speed can be obtained by calculating the derivatives of the polynomial function. Based on the characteristic of rotary objects ,three measuring methods are proposed to measure the pose according to the size of images in the camera planes. The measuring error sources are analyzed and the methods to reduce the measuring error are also put forward. Experiments and theoretical analysis prove the exactness and effectiveness of the proposed measuring methods of speed, and the measuring error of speed is less than 2 %. A new and reliable approach to measure the dynamic parameter of flying target is provided.
作者 崔彦平 葛杏卫 傅其凤
机构地区 河北科技大学机械电子工程学院 天津大学精密测试技术及仪器国家重点实验室
出处 《传感器与微系统》 CSCD 北大核心 2009年第8期37-38,42,共3页 Transducer and Microsystem Technologies
基金 教育部博士点专项科研基金资助项目(20030056017)
关键词 双目视觉 速度测量 飞行目标 最小二乘法 binocular vision speed measurement flying target method of least square
分类号 TP242.6 [自动化与计算机技术—检测技术与自动化装置]
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参考文献6

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  • 1黄俊软.测试误差分析与数学模型[M].国防工业出版社,..
  • 2毛英泰.误差理论与精度分析[M].国防工业出版社,..
  • 3[1]Bijan Shimzadeh. Laser-interferometry-based tracking for dynamic measurement. Industrial Robot, 1998, 25(1): 35~41
  • 4[2]Yuan Jing, Yu S L. End-effector position-orientation measurement. IEEE Transaction on Robotics and Automation,1999, 15(3): 592~595
  • 5[3]McNamee L P, Petriu E M, Spoelder H J W. Photogrammetric calibration of a mobile robot model. In: IEEE ed.Conference Record-IEEE Instrumentation and Measurement Technology Conference, 18th IEEE Instrumentation and Measurement Technology Conference, Budapest,2001(1): 245~250
  • 6[4]Janocha H, Diewald B. New methods of measuring and calibrating robots. In: Proceedings of SPIE, The International Society for Optical Engineering, Intelligent Robots and Computer Vision ⅩⅣ: Algorithms, Techniques, Active Vision, and Materials Handling , Philadelphia, 1995,Bellingham: Society of Photo-Optical Instrumentation Engineers, 1995:688~699
  • 7[5]Van Albada G D. Low-cost pose-measuring system for robot calibration. Robotics and Autonomous Systems,1995, 15(3): 207~227
  • 8[1]Chen Zu-gui, Chen Yi-qing, Sun Cheng-qi, et al. Digital attitude determination and adaptive attitude control system[A]. 12th FAC-Symposium on Automatic Control in Aerospace Control '92[C]. Ottobrunn, Germany, September 7-11, 1992.
  • 9[2]Barbour N, Madden P, Socha M. A micromechanical gyro package with GPS under development for small pointing satellites[R]. Charles Stark Draper Laboratory, Cambridge, MA, 1997.
  • 10[3]Lightsey E G. Analysis of spacecraft attitude measurements using onboard GPS[D]. Stanford University, Stanford, California 94305. AAS 94-063.

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传感器与微系统
2009年 第8期

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