[1]关英姿,康立新.长波红外非制冷光学系统设计[J].红外技术,2008,30(二):079-82.
 GUAN Ying-zi,KANG Li-xin.LWIR Uncooled Optical System Design[J].Infrared Technology,2008,30(二):079-82.
点击复制

长波红外非制冷光学系统设计
分享到:

《红外技术》[ISSN:1001-8891/CN:CN 53-1053/TN]

卷:
30卷
期数:
2008年第二期
页码:
079-82
栏目:
出版日期:
2008-02-20

文章信息/Info

Title:
LWIR Uncooled Optical System Design
文章编号:
1001-8891(2008)02-0079-04
作者:
关英姿1康立新2
1.哈尔滨工业大学 航天学院,黑龙江 哈尔滨 150001;2.哈尔滨精佳光电技术有限公司,黑龙江 哈尔滨 150001
Author(s):
GUAN Ying-zi1KANG Li-xin2
1. School of Astronautics, Harbin Institute of Technology, Harbin Heilongjiang 150001, China;
2. Harbin Jingjia Photoelectricity Technology Co.Ltd, Harbin Heilongjiang 150001, China

关键词:
成像光学红外系统无热化设计光学被动式补偿机械被动式补偿
Keywords:
分类号:
TN21
文献标志码:
A
摘要:
由于温度变化会导致红外光学系统的成像质量变坏,因此,对于工作环境温度在-45~60℃之间的长波红外折射光学系统来说,无热化设计成为光学系统设计的难点和关键。为研究不同的无热化补偿方式的特点,分别设计了基于光学被动式无热化补偿和基于机械被动式无热化补偿的两种长波红外非制冷光学系统,对比分析了两种光学系统的优缺点,给出了选择无热化补偿方法的基本原则。
Abstract:
The change of temperature could cause image degradation for an infrared optical system. So athermalisation becomes the difficulty and key in the designing of LWIR optical systems for working under temperature range of -45~60℃. To study the characteristic of different athermal compensation methods, two kinds of uncooled optical system respectively based on athermal techniques of optical passive compensation and mechanical passive compensation are designed. The basic selection principle of athermal compensation methods is put forward by comparing the merits and faults of the systems.

参考文献/References:

[1] ?吴晓晴,孟军和.红外光学系统无热化设计的途径[J]. 红外与激光工程, 2003, 32(6): 572~576.
[2] ?胡玉禧, 周绍祥, 杨建峰, 等. 红外系统的光机热一体化设计[J]. 红外技术, 2000, 22(2): 32~35.
[3] ?明景谦, 金宁, 郭岚, 等. 红外7.5~10.5 ?m波段折射/衍射光学系统的消热差设计[J]. 红外技术, 2006, 28(5): 261~265.
[4] ?温彦博, 白剑, 侯西云, 等. 红外无热化混合光学系统设计[J]. 光学仪器, 2005, 27(5): 82~86.
[5] ?李娟, 王英瑞, 张宏. 一种机械被动式无热补偿方法[J]. 红外与激光工程, 2006, 35(4): 476~480.
[6] ?吴晓晴, 孟军和. 使用简单机械结构实现红外光学系统无热化[J]. 红外与激光工程, 2005, 34(4): 391~393.

相似文献/References:

[1]李延东,杨俊彦,李亚文,等.AM-OLED微型显示器在红外系统中的应用[J].红外技术,2012,34(04):200.
 LI Yan-dong,YANG Jun-yan,LI Ya-wen,et al.Application of AM-OLED Microdisplay in Infrared Display Systems[J].Infrared Technology,2012,34(二):200.
[2]付跃刚,黄蕴涵.红外双视场枪瞄光学系统设计[J].红外技术,2014,36(6):451.[doi:10.11846/j.issn.1001_8891.201406006]
 FU Yue-Gang,HUANG Yun-Han.Design of Infrared Aiming Optical System[J].Infrared Technology,2014,36(二):451.[doi:10.11846/j.issn.1001_8891.201406006]
[3]薛 军,邹建华,张永亮.红外跟踪测量系统图像处理电路的设计[J].红外技术,2014,36(8):652.[doi:10.11846/j.issn.1001_8891.201408010]
 XUE Jun,ZOU Jian-hua,ZHANG Yong-liang.Design of Image-processing Circuit in Infrared Tracking and Measuring System[J].Infrared Technology,2014,36(二):652.[doi:10.11846/j.issn.1001_8891.201408010]
[4]张宪亮,刘若凡,苏红雨,等.红外系统杂散光测量装置[J].红外技术,2014,36(12):961.[doi:10.11846/j.issn.1001_8891.201412005]
 ZHANG Xian-liang,LIU Ruo-fan,SU Hong-yu,et al.Stray Light Measurement Equipment for Infrared Optical System[J].Infrared Technology,2014,36(二):961.[doi:10.11846/j.issn.1001_8891.201412005]
[5]任国栋,张良,兰卫华,等.红外成像系统冷反射的定量分析[J].红外技术,2016,38(4):290.[doi:10.11846/j.issn.1001_8891.201604003]
 REN Guodong,ZHANG Liang,LAN Weihua,et al.Quantitative Analysis of the Narcissus of Infrared Imaging System[J].Infrared Technology,2016,38(二):290.[doi:10.11846/j.issn.1001_8891.201604003]
[6]李 蕾,张 葆,李全超.机载红外系统主反射镜的拓扑优化设计[J].红外技术,2016,38(8):648.[doi:10.11846/j.issn.1001_8891.201608004]
 LI Lei,ZHANG Bao,LI Quanchao.Topology Optimization of Primary Mirror in Airborne Infrared System[J].Infrared Technology,2016,38(二):648.[doi:10.11846/j.issn.1001_8891.201608004]
[7]张发平,张华卫.基于二元衍射面的长波无热化光学系统设计[J].红外技术,2020,42(1):025.[doi:10.11846/j.issn.1001_8891.202001004]
 ZHANG Faping,ZHANG Huawei.Design of Long-wave Athermal Optical System Based on Binary Diffraction Surface[J].Infrared Technology,2020,42(二):025.[doi:10.11846/j.issn.1001_8891.202001004]

备注/Memo

备注/Memo:
收稿日期:2007-11-12
作者简介:关英姿(1968-),女,教授,主要研究方向:光学成像制导仿真。

更新日期/Last Update: 2014-09-26