摘要
提出了一种针对星载激光雷达在轨高精度光轴监测与标定需求的多光轴监测方法,该方法基于主动激光光源。通过使用785 nm的激光,分束后分别照射到星敏感器的基准棱镜和接收望远镜的取光棱镜,反射信号被聚焦至监视相机的焦平面,实现了对接收光轴及星敏光轴的精确监测。此外,监视相机还同步采集发射激光的部分能量,用于测量监测发射光轴。文中详细描述了光学系统的设计流程及关键组件的优化方案,并通过地面真空环境试验及在轨监测数据进行了验证。设计结果表明,各监视通道的成像质量达到了衍射极限,收发光轴的设计精度分别为0.09μrad和2.28μrad,关键组件取光棱镜的温控精度达到了±0.2℃。地面的真空热光试验结果进一步验证了该方案的高精度光轴监视能力,收发光轴的监测精度均优于3μrad。最后通过分析激光雷达入轨后的测量数据,确认了视轴监测系统的工作稳定性,成功实现了在轨的高精度光轴监视。该研究成果为星载激光雷达提供了一种有效的在轨高精度光轴监测与标定解决方案。
Objective With the increasing seriousness of global atmospheric environmental pollution,spaceborne lidar,as a new type of active remote sensing instrument,has become an important load for global atmospheric measurement,which can achieve high-precision measurement of atmospheric components such as greenhouse gases,particulate matter,and aerosols.Compared with the passive detection of spaceborne cameras,lidar has more stringent requirements for the stability of optical systems.The mechanical impact during the orbiting process,the change of gravity field during the orbiting operation,the change of temperature,the release of internal stress,and the jitter of the satellite platform will cause the structural deformation of the main optical machine of the lidar,thereby destroying the consistency of the optical axis of the radar transceiver and causing a decrease in detection efficiency.In addition,the change of the direction of the lidar optical axis relative to the star sensor will lead to the deviation of the radar optical axis relative to the reference measurement attitude.Therefore,high-precision transceiver optical axis monitoring and matching technology is necessary for active detection of remote sensing functions.The optical axis monitoring unit is used to monitor the real-time variation of the transceiver optical axis,which is an important part of the optical axis matching feedback mechanism.Methods Figure 1 shows the main components of the visual axis monitoring system,including the active 785 nm reference light source,the visual axis camera,the CCD focusing lens group,the eyepiece,the receiving optical axis prism,the star sensor reference mirror,the beam combiner and the beam splitter.The active reference light source in the system uses a laser diode with a wavelength of 785 nm.After the tail fiber output laser is collimated and shaped,it first passes through the beam splitter M1.In this process,about one-tenth of the beam energy is reflected into the surveillance camera as a reference optical axis.Subsequently,the reference light is beam-divided again by 1:1 through the M2 mirror.This part of the light is reflected by the reference prism of the star sensor and imaged on the surveillance camera to capture the information of the star-sensitive optical axis.The light beam separated by the M2 mirror is reflected by a hollow mirror and enters the telescope system,and is reflected back to the surveillance camera through a light-taking prism located next to the secondary mirror,so that the direction change information of the received optical axis can be obtained.In addition,the emitted laser is split by a beam splitter before output,and a small amount of emitted laser enters the surveillance camera by turning and combining the beams to obtain the change information of the laser emission optical axis.The simulation results show that the imaging quality of the four optical axis monitoring channels reaches the diffraction limit level,and the design accuracy of the receiving and transmitting optical axis monitoring can reach 0.09μrad and 2.28μrad respectively.Results and Discussions The experimental verification of spaceborne lidar in vacuum and space thermal environment was carried out.A test system in vacuum environment was built to calibrate the optical axis pointing of lidar.The optical axis change data measured by the optical axis monitoring unit and the tank test system were compared.The test results are shown in Fig.12.The pointing fluctuation of the transmitting optical axis measured by the optical axis monitoring unit is±1.14μrad(corresponding to a pixel jump).At this time,the pointing jitter of the transmitting laser measured by the monitoring system in the tank is better than±1.5μrad;the pointing fluctuation of the receiving optical axis measured by the optical axis monitoring unit is±1.2μrad,and the corresponding jitter measured by the tank monitoring system is±3.5μrad.By comparison,it is found that both of them have the same periodic fluctuation,and the fluctuation cycle is consistent with the track thermal environment cycle.The optical axis monitoring accuracy of the transmitting optical axis is limited by the angular resolution of the channel of 2.28μrad.There is a deviation of about 3μrad between the visual axis system for monitoring the receiving optical axis and the in-tank test system.The reason is that the beam has a long transmission path in the in-tank test system,which is easily affected by vibration and temperature deformation during the operation of the vacuum equipment.The optical axis data after the stable operation of the lidar is analyzed.The optical axis change data is shown in Fig.13.The data analysis shows that the stability of the optical axis of the lidar is better than 3μrad after the stable operation of the lidar in orbit.Conclusions In this paper,a space-based multi-optical axis monitoring method is proposed for the on-orbit stability requirements of Atmospheric Environment Monitoring Satellite(DQ-1)Aerosol and Carbon dioxide Detection Lidar(ACDL),and a set of lidar optical axis monitoring optical machine system is designed.By using the integrated imaging scheme of active laser light source,the on-orbit synchronous high-precision monitoring of lidar transceiver optical axis under space-based coordinate reference is successfully realized.The high precision and high reliability of the monitoring technology in the space environment are verified by the vacuum thermo-optical calibration test in the ground space environment.After the lidar is launched into orbit,the optical axis monitoring unit works normally in orbit.The optical axis monitoring unit used in this paper has high environmental reliability and stability,and can be applied to other optical axis monitoring modules of active and passive space optical loads,which has important reference value and guiding significance.
作者
万渊
李蕊
张扬
袁金如
熊恒
周国威
刘继桥
侯霞
WAN Yuan;LI Rui;ZHANG Yang;YUAN Jinru;XIONG Heng;ZHOU Guowei;LIU Jiqiao;HOU Xia(Aerospace Laser Technology and System Department,Shanghai Institute of Optics and Fine Mechanics,Chinese Academy of Sciences,Shanghai 201800,China;Center of Materials Science and Optoelectronics Engineering,University of Chinese Academy of Sciences,Beijing 100049,China;Shanghai Institute of Satellite Engineering,Shanghai 201109,China)
出处
《红外与激光工程》
EI
CSCD
北大核心
2024年第6期61-70,共10页
Infrared and Laser Engineering
基金
中国科学院战略性重点研究计划项目(XDA19090100)。
关键词
主动遥感
星载激光雷达
光轴监测单元
光轴匹配
active remote sensing
space-borne lidar
optical axis monitoring unit
optical axis matching