[1]荆卫国,孙明昭,李永涛.大动态范围微光夜视系统强光适应性试验方法研究[J].红外技术,2019,41(7):689-692.[doi:10.11846/j.issn.1001_8891.201907016]
 JING Weiguo,SUN Mingzhao,LI Yongtao.Novel Experimental Method of Intense Light Adaptability of Night Vision Systems with Large Dynamic Range[J].Infrared Technology,2019,41(7):689-692.[doi:10.11846/j.issn.1001_8891.201907016]
点击复制

大动态范围微光夜视系统强光适应性试验方法研究
分享到:

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

卷:
41卷
期数:
2019年第7期
页码:
689-692
栏目:
出版日期:
2019-07-20

文章信息/Info

Title:
Novel Experimental Method of Intense Light Adaptability of Night Vision Systems with Large Dynamic Range

文章编号:
1001-8891(2019)07-0689-04
作者:
荆卫国孙明昭李永涛
中国华阴兵器试验中心
Author(s):
JING WeiguoSUN MingzhaoLI Yongtao
Huayin ordance Test Center of China
关键词:
动态范围微光夜视系统像增强器照度
Keywords:
dynamic rangelow light night vision systemimage intensifierilluminance
分类号:
TN223
DOI:
10.11846/j.issn.1001_8891.201907016
文献标志码:
A
摘要:
微光夜视系统具有功耗低、重量轻、图像质量符合人眼观察习惯等应用优势,目前仍是世界各国使用最广泛、装备量最大的军用夜视装备。随着微光夜视系统核心器件——像增强器动态范围的不断扩大,对有效开展系统强光适应性试验提出了新的要求。为准确、客观评价大动态范围夜视系统的强光适应性能,本文从理论上修正了光学系统中像增强器阴极面照度的计算模型,并依据像增强器强光性能参数,设计了试验方法。经外场试验验证,该方法可以较为准确评价大动态微光夜视系统强光适应性,可为微光夜视装备强光适应性试验提供技术支撑。
Abstract:
Low light night vision systems have the advantages of low power consumption, light weight, and image quality in line with the observation habits of human eyes. These systems are still the most widely used military night vision systems in the world. With the expansion of image intensifier dynamic range, novel requirements have been established for effective testing of strong light adaptability. To accurately and objectively evaluate strong light adaptability of night vision systems with large dynamic range, the calculation model of image intensifier cathode illumination in the optical system is modified theoretically. The proposed method can accurately evaluate the strong light adaptability of large dynamic range night vision systems and provide technical support for strong light adaptability testing of low light night vision equipment.

参考文献/References:

[1]? ?郭晖, 向世明, 田民强. 微光夜视技术发展动态评述[J]. 红外技术, 2013, 35(2): 63-68.
GUO Hui, XIANG Shiming, TIAN Minqiang. Review on the development of low-light night vision technology[J]. Infrared Technology, 2013, 35(2): 63-68.
[2]? ?周立伟. 光电子成像:走向新的世纪[J]. 北京理工大学学报, 2002, 22(1): 1-12.
ZHOU Liwei. Optoelectronic imaging: towards a new century[J]. Journal of Beijing Institute of Technology, 2002, 22(1): 1-12.
[3]? ?艾克聪. 微光夜视技术的进展及展望[J]. 应用光学, 2006, 27(4): 303-307.
AI Kecong. Progress and prospect of LLL night vision technology[J]. Applied Optics, 2006, 27(4): 303-307.
[4]? ?周立伟. 光电子成像:回顾和展望[J]. 中国计量学院学报, 2001, 12(2): 25-29.
ZHOU Liwei. Optoelectronic imaging: review and prospect[J]. Journal of China Institute of Metrology, 2001, 12(2): 25-29.
[5]? ?谭显裕. 微光夜视和红外成像技术的发展及军用前景[J]. 航空兵器, 2001(3): 29-34.
TAN Xianyu. Development and military prospect of low-light night vision and infrared imaging technology[J]. Aeronautical Weapons, 2001(3): 29-34.
[6]? ?向世明, 倪国强. 光电子成像器件原理[M]. 北京: 国防工业出版社, 2003.
XIANG Shiming, NI Guoqiang. Principle of Optoelectronic Imaging Device[M]. Beijing: national defense industry press, 2003.
[7]? 邓广绪, 延波, 智强, 等. 微光像增强器自动门控电源技术研究[J]. 红外技术, 2012, 34(3): 155-158.
DENG Guangxu, YAN Bo, ZHI Qiang, et al. Research on automatic gated power supply of low-light image intensifier[J]. Infrared Technology, 2012, 34(3): 155-158.
[8]? 拜晓锋, 尹雷, 程宏昌, 等. 微通道板像增强器动态范围测试技术研究[J]. 光学与光电技术, 2012, 10(5): 21-23.
BAI Xiaofeng, YIN Lei, CHENG Hongchang, et al. Research on dynamic range testing tecnology of micro-channel plate image intensifier[J]. Optics and Optoelectronics Technology, 2012, 10(5): 21-23.
[9]? 中国人民解放军总装备部. GJB 4262-2001侦察微光夜视仪战术性能试验方法[S]. 总装备部军标出版发行部, 2001.
General armament department of the people’s liberation army. GJB 4262-2001 tactical performance test method for reconnaissance LLL night vision instrument[S]. General armament department, military standard publishing department, 2001.

相似文献/References:

[1]延波,智强,李军国,等. 基于自动门控电源的微光像增强器动态范围研究[J].红外技术,2013,35(05):300.
 YAN Bo,ZHI Qiang,LI Jun-guo,et al. Study of Image Intensifier Dynamic Range Based on Auto-gating Power Source[J].Infrared Technology,2013,35(7):300.
[2]王永攀,郭方敏.高灵敏度量子点-量子阱光电探测器的大动态范围读出设计[J].红外技术,2011,33(06):336.
 WANG Yong-pan,GUO Fang-min.Wide Dynamic Range Readout Circuit Design?on High Sensitivity Quantum Dot-in-Well Photodetector[J].Infrared Technology,2011,33(7):336.
[3]范永杰,金伟其,刘斌,等.FLIR公司热成像细节增强DDE技术的分析[J].红外技术,2010,32(3):161.
 FAN Yong-jie,JIN Wei-qi,LIU Bin,et al.An Analysis of Digital Detail Enhancement (DDE) TechnologyDeveloped by FLIR[J].Infrared Technology,2010,32(7):161.
[4]王锐,邵晓鹏,徐军,等.基于定标积分时间法提高红外成像系统动态范围的研究[J].红外技术,2009,31(7):381.
 WANG Rui,SHAO Xiao-peng,XU Jun,et al.Study on Improving Dynamic Range of Infrared Imaging System?Based on Calibrating Integration Time[J].Infrared Technology,2009,31(7):381.
[5]孔琛,孙坚.线性灰度变换算法在红外测温系统中应用[J].红外技术,2008,30(八):465.
 KONG Chen,SUN Jian.Application of the Linear Gray Level Transformation Methodin Infrared Temperature Measurement System[J].Infrared Technology,2008,30(7):465.

备注/Memo

备注/Memo:
收稿日期:2019-04-12;修订日期:2019-05-29.
作者简介:荆卫国(1964-),男,河南三门峡人,高级工程师,主要从事侦察情报装备试验鉴定工作。E-mail:1134686784@qq.com。
基金项目:观测装备侦察能力试验关键技术研究(1600010237)。

更新日期/Last Update: 2019-07-12