中国光学
中國光學
중국광학
Chinese Journal of Optics
2015年
6期
1027-1034
,共8页
光学制造%在线检测%大口径反射镜%精确对准%图像配准
光學製造%在線檢測%大口徑反射鏡%精確對準%圖像配準
광학제조%재선검측%대구경반사경%정학대준%도상배준
optical fabrication%optical testing online%large-aperture mirror%precise alignment%image registra-tion
本文提出了基于特殊点对靶标的快速对准装置,实现机床加工臂和检测臂初始扫描位置自动高精度复位。靶标由外围区域四组放大倍率标定点对和中心区域大小对准点对组成;对准装置经初次使用前的畸变校正后,每次自动识别靶标区域完成自动对焦;根据外围点对进行放大倍率标定;自动识别中心大小点对并对其进行坐标定位;根据当前点对靶标位置计算与理想位置角度量和平移量偏差,指导机床转台和导轨互相配合,迭代调整直至完成精确对准。实验表明该方法对准精度约为5μm,优于几十μm 的机械定位精度,更利于实现超高精度光学加工的快速收敛,提高大口径反射镜加工效率。
本文提齣瞭基于特殊點對靶標的快速對準裝置,實現機床加工臂和檢測臂初始掃描位置自動高精度複位。靶標由外圍區域四組放大倍率標定點對和中心區域大小對準點對組成;對準裝置經初次使用前的畸變校正後,每次自動識彆靶標區域完成自動對焦;根據外圍點對進行放大倍率標定;自動識彆中心大小點對併對其進行坐標定位;根據噹前點對靶標位置計算與理想位置角度量和平移量偏差,指導機床轉檯和導軌互相配閤,迭代調整直至完成精確對準。實驗錶明該方法對準精度約為5μm,優于幾十μm 的機械定位精度,更利于實現超高精度光學加工的快速收斂,提高大口徑反射鏡加工效率。
본문제출료기우특수점대파표적쾌속대준장치,실현궤상가공비화검측비초시소묘위치자동고정도복위。파표유외위구역사조방대배솔표정점대화중심구역대소대준점대조성;대준장치경초차사용전적기변교정후,매차자동식별파표구역완성자동대초;근거외위점대진행방대배솔표정;자동식별중심대소점대병대기진행좌표정위;근거당전점대파표위치계산여이상위치각도량화평이량편차,지도궤상전태화도궤호상배합,질대조정직지완성정학대준。실험표명해방법대준정도약위5μm,우우궤십μm 적궤계정위정도,경리우실현초고정도광학가공적쾌속수렴,제고대구경반사경가공효솔。
A precise alignment method based on special target and fast point matching is proposed.The target includes four point-pairs for magnification calibration in peripheral area and one large-small point-pair for reg-istration in center area.Distortion calibration of the alignment system is completed at the first time of opera-tion.When the optical testing arm or the fabrication arm reset,the target area is focused automatically.The image captured is used to calculate the magnification of the system.Then,the large-small point-pair is located and the angle of the line through the two points is employed to adjust the swivel table,while the distance be-tween the two points is applied for correction of the guide rail.The procedure is repeated iteratively until cur-rent location coincides with the ideal position.It is proved that the alignment accuracy of the method is about 5 μm,which is better than the precision of mechanical approach and is helpful for rapid and precise optical fabrication,and can improve the consistency of the optical testing simulation path and the practical fabrication path.