1 中国科学院自适应光学重点实验室,四川 成都 610209
2 中国科学院光电技术研究所,四川 成都 610209
3 中国科学院大学,北京 100049
对太阳大气进行大视场高分辨力光学成像观测是开展太阳物理、空间天气等基础与应用研究的重要前提。对于地基太阳望远镜而言,为了消除地球大气湍流对光学系统的影响,自适应光学是高分辨力成像观测必备的技术手段,与此同时,为了突破大气非等晕性对传统自适应光学校正视场的限制,近年来多层共轭自适应光学技术等大视场自适应光学得到极大发展。本文首先梳理国外太阳自适应光学系统研制情况,重点介绍国内太阳自适应光学技术发展及应用情况,并进一步介绍了后续大视场太阳自适应光学技术发展情况以及目前所取得的成果。
太阳观测 自适应光学 多层共轭自适应光学 solar observation adaptive optics multi-conjugate adaptive optics
Author Affiliations
Abstract
1 The Key Laboratory on Adaptive Optics, Chinese Academy of Sciences, Chengdu 610209, China
2 The Laboratory on Adaptive Optics, Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu 610209, China
3 University of Chinese Academy of Sciences, Beijing 100049, China
A second generation solar adaptive optics (AO) system is built and installed at the 1-m New Vacuum Solar Telescope (NVST) of the Fuxian Solar Observatory (FSO) in 2015. The AO high-order correction system consists of a 151-element deformable mirror (DM), a correlating Shack–Hartmann (SH) wavefront sensor (WFS) with a 3500 Hz frame rate, and a real-time controller. The system saw first light on Mar. 16, 2015. The simultaneous high-resolution photosphere and chromosphere images with AO are obtained. The on-sky observational results show that the contrast and resolution of the images are apparently improved after the wavefront correction by AO.
010.1080 Active or adoptive optics 110.1080 Active or adoptive optics 110.0115 Imaging through turbulent media Chinese Optics Letters
2015, 13(12): 120101
中北大学电子测试技术国防重点实验室, 仪器科学与动态测试教育部重点实验室, 山西 太原 030051
红外光源辐射利用率是制造高性能红外系统的关键, 准直透镜因其减少红外光源的广角散射而大幅提高红外光源利用率。针对 MEMS红外光源设计 CaF2高红外透射材料的双凸曲面结构准直辐射透镜, 使红外光线收敛呈准直辐射; 由 MEMS红外光源封装确定透镜最佳口径 r=6.48 mm, 透镜焦距 f=7.2 mm, 透镜厚度 d.≤2 mm, 用 Zemax光学软件仿真优化, 得出中间层厚度 d=0.309 mm。并进行透镜的聚光光路仿真分析和效果验证, 为定向辐射 MEMS红外光源研发提供最优的原型尺寸参数, 极大提高设计效率。
MEMS红外光源 准直透镜 聚光封装 收敛辐射 MEMS infrared source collimating encapsulation light-gathering package convergence of radiation
Author Affiliations
Abstract
1 Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu 610209, China
2 Key Laboratory on Adaptive Optics, Chinese Academy of Sciences, Chengdu 610209, China
3 Graduate University of Chinese Academy of Sciences, Beijing 100049, China
A 127-element adaptive optical system has been developed and integrated into a 1.8-m astronomical telescope in September 2009. In addition, the first light on a high-resolution imaging for stars has been achieved (September 23, 2009). In this letter, a 127-element adaptive optical system for 1.8-m telescope is described briefly. Moreover, star observation results in the first run are reported. Results show that the angular resolution of the system after adaptive optics correction can attain 0.1 arcsec, which approaches the diffraction limit of 1.8-m telescope at 700–900 nm band.
自适应光学系统 哈特曼传感器 跟踪 首次结果 性能 220.1080 Active or adoptive optics 010.1285 Atmospheric correction 010.1330 Atmospheric turbulence Chinese Optics Letters
2010, 8(11): 1019
Author Affiliations
Abstract
1 Key Laboratory on Adaptive Optics, Chinese Academy of Sciences, Chengdu 610209, China
2 Laboratory on Adaptive Optics, Institute of Optics and Electronics, Chinese Academy of Sciences, Chengdu 610209, China
3 Yunnan Astronomical Observatory, National Astronomical Observatories,Chinese Academy of Sciences, Kunming 650011, China
A 37-element solar adaptive optics (AO) system was built and installed at the 26-cm solar fine structure telescope of Yunnan Astronomical Observatory. The AO system is composed of a fine tracking loop with a tip/tilt mirror and a correlation tracker, a high-order correction loop with a 37-element deformable mirror, a correlating Shack-Hartmann wavefront sensor based on the absolute difference algorithm, and a real time controller. The system was completed on Sep. 28, 2009 and was used to obtain AO-corrected highresolution solar images. The contrast and resolution of the images are clearly improved after wavefront correction by AO. To the best of out knowledge, this system is the first solar AO system in China.
自适应光学 相关跟踪器 相关夏克-哈特曼波前探测器 太阳黑子 太阳米粒 010.1080 Active or adoptive optics 110.1080 Active or adoptive optics Chinese Optics Letters
2010, 8(10): 966
1 中国科学院 光电技术研究所自适应光学研究室,成都 610209;中国科学院研究生院,北京 100039
2 中国科学院 光电技术研究所自适应光学研究室;自适应光学重点实验室,成都 610209
本文提出了一种基于薄板径向支撑的高速压电倾斜镜。首先根据拉格朗日方程建立了这种基于薄板径向支撑的高速压电倾斜镜简化模型的动力学方程,然后推导出了其倾斜方向谐振频率理论表达式;根据理论表达式可以预测倾斜镜的动态性能。在理论分析的基础上,我们制作了这种薄板结构,将其加入到原有结构倾斜镜中,进行了频响测试以及角行程测试分析。比较理论分析和实验测试分析的结果,证实了薄板部件的加入对于倾斜镜应用带宽的提高有显著作用。
高速压电倾斜镜 薄板径向支撑 动力学分析 自适应光学系统 piezoelectric fast steering mirror (FSM) radial fasten thin plane dynamic analysis adaptive optical system
中国科学院光电技术研究所,四川 成都 610209
云南天文台1.2m望远镜61单元自适应光学系统已经完成升级改造并投入使用。该自适应光学系统主要由倾斜跟踪控制回路、高阶校正回路以及高分辨力成像系统组成。为了提高系统的跟踪精度,倾斜跟踪控制回路由两级倾斜校正回路串联而成,用于校正望远镜的跟踪误差和大气湍流引起的倾斜跟踪误差。高阶校正回路主要由一套哈特曼波前传感器、一块61单元变形反射镜以及一套高速数字波前处理机组成。系统中哈特曼波前传感器的工作波段为400~700nm,系统成像波段为700~900nm。在介绍61单元自适应光学系统各组成部分的基础上,对该系统的性能进行了分析,并给出了实际天文恒星目标的高分辨力自适应光学成像观测结果。
自适应光学 波前传感器 跟踪 性能分析 adaptive optics Hartmann-Shack wavefront sensor tracking performance analysis
1 中国科学院光电技术研究所,成都,610209
2 南京大学天文系,南京,210093
提出一种利用高速倾斜反射镜对太阳像进行平场处理的新方法。介绍了此方法的原理和实际工作过程,并给出了实验结果。结果表明,应用高速倾斜反射镜可以非常有效地对太阳像进行平场处理,提高太阳像成像质量。
天文仪器 太阳望远镜 平场 倾斜镜
