航天返回与遥感
航天返迴與遙感
항천반회여요감
SPACECRAFT RECOVERY & REMOTE SENSING
2013年
3期
9-15
,共7页
赵惠%樊学武%邹刚毅%庞志海%王炜%任国瑞%杜云飞%苏宇
趙惠%樊學武%鄒剛毅%龐誌海%王煒%任國瑞%杜雲飛%囌宇
조혜%번학무%추강의%방지해%왕위%임국서%두운비%소우
变焦距%变形镜%分离主镜%光学杠杆%试验验证%空间遥感
變焦距%變形鏡%分離主鏡%光學槓桿%試驗驗證%空間遙感
변초거%변형경%분리주경%광학강간%시험험증%공간요감
changeable focal length%deformable mirror%segmented primary mirror%optical leveraging%experimental demonstration%space remote sensing
首先介绍了详普查相结合的空间光学观测技术在空间观测领域的重要应用,总结了详普查空间光学观测的实现方法和发展现状。分析了变形镜变焦的理论设计思路,提出了采用变形镜结合光学杠杆作用实现无运动部件变焦光学系统的设计方案,设计了一个变焦比为4的大视场四反射变焦光学系统。通过视场离轴消除了中心遮拦,其中第三镜为变形镜;通过控制其曲率的变化来实现系统焦距从625mm 到2.5m 的变换;为了分担变形镜所承担的光焦度,采用了分离主镜的光学设计方案,最终光学系统的成像性能达到衍射极限。同时,研制了缩比系统进行了关键技术原理性试验验证,并成功实现了基于无运动部件的4倍变倍成像效果。该技术的研究对于在未来构建新型的高分辨率详普查结合型有效载荷有一定借鉴作用。
首先介紹瞭詳普查相結閤的空間光學觀測技術在空間觀測領域的重要應用,總結瞭詳普查空間光學觀測的實現方法和髮展現狀。分析瞭變形鏡變焦的理論設計思路,提齣瞭採用變形鏡結閤光學槓桿作用實現無運動部件變焦光學繫統的設計方案,設計瞭一箇變焦比為4的大視場四反射變焦光學繫統。通過視場離軸消除瞭中心遮攔,其中第三鏡為變形鏡;通過控製其麯率的變化來實現繫統焦距從625mm 到2.5m 的變換;為瞭分擔變形鏡所承擔的光焦度,採用瞭分離主鏡的光學設計方案,最終光學繫統的成像性能達到衍射極限。同時,研製瞭縮比繫統進行瞭關鍵技術原理性試驗驗證,併成功實現瞭基于無運動部件的4倍變倍成像效果。該技術的研究對于在未來構建新型的高分辨率詳普查結閤型有效載荷有一定藉鑒作用。
수선개소료상보사상결합적공간광학관측기술재공간관측영역적중요응용,총결료상보사공간광학관측적실현방법화발전현상。분석료변형경변초적이론설계사로,제출료채용변형경결합광학강간작용실현무운동부건변초광학계통적설계방안,설계료일개변초비위4적대시장사반사변초광학계통。통과시장리축소제료중심차란,기중제삼경위변형경;통과공제기곡솔적변화래실현계통초거종625mm 도2.5m 적변환;위료분담변형경소승담적광초도,채용료분리주경적광학설계방안,최종광학계통적성상성능체도연사겁한。동시,연제료축비계통진행료관건기술원이성시험험증,병성공실현료기우무운동부건적4배변배성상효과。해기술적연구대우재미래구건신형적고분변솔상보사결합형유효재하유일정차감작용。
The important applications of space optical observation technologies based on the general and detailed investigation imaging are first introduced, and the internal and overseas optical observation methods and current status of development are summarized. Then, the design theory for zoom optical systems using de-formed mirrors (DM) is introduced, and a zoom optical system design method based on DMs without any me-chanical moving parts is put forward. Finally, a four-mirror reflective zoom optical system with large field-of-view (FOV) is designed, with the zoom ratio 4. The central obscuration is eliminated by making the FOV non-coaxial. The third mirror is DM, the curvature of which is controlled to make the focal length change from 2.5m to 10m. The separate primary mirrors for the different focal positions are used in order to reduce the optical-power changing range of DM. The performance of the final optical system is diffraction limited. At the same time, the experiments have been carried out and the results demonstrate the effectiveness of the deform-able mirror based on optical zooming without moving elements involved.
