红外与激光工程
紅外與激光工程
홍외여격광공정
INFRARED AND LASER ENGINEERING
2015年
7期
2182-2188
,共7页
劳达宝%周维虎%李万红%石冬%林心龙
勞達寶%週維虎%李萬紅%石鼕%林心龍
로체보%주유호%리만홍%석동%림심룡
测角%柱面光栅%误差补偿%谐波%遗传算法
測角%柱麵光柵%誤差補償%諧波%遺傳算法
측각%주면광책%오차보상%해파%유전산법
angle measurement%cylindrical grating%error compensation%harmonic%genetic algorithm
高精度角度测量装置是保证旋转设备精度和性能的关键,广泛应用于测量跟踪仪器中,特别是对于大尺寸坐标测量仪器,测角相比于测距是制约坐标测量精度的瓶颈。在精密一维轴系平台上,采用高精度柱面光栅及四个读数头构建测角装置,对传感器本身、安装及轴系跳动等误差因素对测角精度的影响进行了详细分析。基于角度测量标准器具校准角度测量误差,对误差数据进行谐波分析。基于遗传算法提出了一种参数优化方法,建立误差补偿模型,对测角误差进行了补偿。实验结果显示,补偿后柱面光栅测角误差减少为±0.7",证明了误差补偿算法的有效性,显著地提高了角度测量精度。
高精度角度測量裝置是保證鏇轉設備精度和性能的關鍵,廣汎應用于測量跟蹤儀器中,特彆是對于大呎吋坐標測量儀器,測角相比于測距是製約坐標測量精度的瓶頸。在精密一維軸繫平檯上,採用高精度柱麵光柵及四箇讀數頭構建測角裝置,對傳感器本身、安裝及軸繫跳動等誤差因素對測角精度的影響進行瞭詳細分析。基于角度測量標準器具校準角度測量誤差,對誤差數據進行諧波分析。基于遺傳算法提齣瞭一種參數優化方法,建立誤差補償模型,對測角誤差進行瞭補償。實驗結果顯示,補償後柱麵光柵測角誤差減少為±0.7",證明瞭誤差補償算法的有效性,顯著地提高瞭角度測量精度。
고정도각도측량장치시보증선전설비정도화성능적관건,엄범응용우측량근종의기중,특별시대우대척촌좌표측량의기,측각상비우측거시제약좌표측량정도적병경。재정밀일유축계평태상,채용고정도주면광책급사개독수두구건측각장치,대전감기본신、안장급축계도동등오차인소대측각정도적영향진행료상세분석。기우각도측량표준기구교준각도측량오차,대오차수거진행해파분석。기우유전산법제출료일충삼수우화방법,건립오차보상모형,대측각오차진행료보상。실험결과현시,보상후주면광책측각오차감소위±0.7",증명료오차보상산법적유효성,현저지제고료각도측량정도。
High precision angle measuring unit, which is the key to ensure accuracy and performance of rotary equipments, is extensively applied in measuring and tracking apparatuses. In regard to large-scale coordinate measuring instruments, angle measurement is the bottleneck to enhance instruments’ coordinate measurement accuracy by comparing with distance measurement. High accuracy cylindrical grating and four reading heads were adopted to build angle measuring unit for precise one-dimension turntable platform, then the influence on angle measuring accuracy by sensor itself, installation and axis shafting were analyzed in detail. Angle measuring error was calibrated by standard device and analyzed with harmonic method. A parameter optimization method based on genetic algorithm was proposed to develop error compensating model, by which angle measurement error was compensated. The experimental results show that cylindrical grating angle measuring error is reduced to ±0.7" after compensation, which demonstrates that the compensation method is effective to improve accuracy obviously.
