近红外星点目标成像系统噪声抑制方法研究
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摘要
白天星敏感器技术是星敏感器技术的一个重要发展方向。研究白天星敏感器技术是将现有星敏感器推广应用于机载、舰载、弹载等多平台的前提和基础。以星点目标为探测对象,研究近红外波段成像系统,开展白天观星试验等工作,是研究白天星敏感器技术的一种有效方案和技术途径。
本文围绕近红外星点目标成像系统中的一项关键技术——噪声抑制方法展开研究。对星点目标成像前和成像后两个阶段噪声的抑制方法进行了深入的研究,对于解决白天星敏感器中的关键问题具有重要意义。
在星点目标成像前,对低噪声红外成像电路设计技术进行了研究。在理论分析的基础上,进行了低噪声CCD驱动电路和噪声抑制电路的设计,完成了CCD星相机的设计和室内成像实验。研究了红外星相机的噪声抑制技术,包括低噪声驱动电路、信号获取电路和制冷电路的设计技术、相机自带两点法非均匀性校正方法等。然后设计了外场观星试验方案,搭建了试验系统,完成了白天观星试验,采集了大量的红外星图,验证了试验方案的可行性和噪声抑制措施的有效性。
星点目标成像后,针对红外星图中的单点噪声,提出了基于4领域和基于列向量扫描的单点噪声抑制方法;针对红外星图中的条纹噪声,提出了列直方图偏移校正(CHOC)和列均值偏移校正(CMOC)两种算法。并用外场实拍星图完成了对上述算法噪声抑制效果的验证,结果显示,去除单点噪声和条纹噪声后,星图质量得到了较大的改善,星图的星点目标峰值信噪比提高了近2倍。
为进一步提高星点背景对比度,本文研究了多种背景滤波算法,在实验分析的基础上提出了一种适用于红外星图的wiener2_top-hat组合滤波方法。用模拟理想星图与外场观测星图叠加构成合成星图的方法,对文中算法的滤波效果进行验证,分析了星点目标峰值信噪比的变化和星点质心的偏移误差。分析的结果表明:文中序列算法处理后星图的峰值信噪比提高到了原始星图的3~4倍,星点质心偏移仅为1/30像素,算法具有较高的精度。
本文围绕近红外星点目标成像系统的噪声抑制方法展开研究。分析了系统中各种噪声的特性和抑制方法,提出了具有针对性的解决思路和方案,在外场试验和星图处理实验中取得了良好的效果,为进一步开展近红外白天观星试验研究奠定了基础。
Daytime star sensor technology is an important development direction of starsensor technology. The research on daytime star sensor technology is the premise andfoundation of extending the application platform of present star sensor to airborne,shipborne, missileborne and other platforms. Using the stars as the detecting targets,researching infrared imaging systems and launching daytime star observationexperiments is one effective scheme and technical approach of daytime star sensortechnology research.
The thesis did research around the denoising methods, which was one keytechnology of infrared star point target imaging system. The thesis made intensive studyon denoising methods in two sections: before and after star point target imaging, whichwas of great significance in resolving the key problems of daytime star sensor.
Before the star point target imaging, the technology of designing low noise infraredimaging circuits was researched. On the basis of theoretical analysis, a low noise CCDdriving circuit and a denoising circuit were designed, a CCD star camera was designedand an inroom imaging experiment was accomplished. Denoising methods for infraredstar camera were researched, which contain the design technique of low noise drivingcircuit, signal acquisition circuit, cooling circuit, two-piont nonuniformity correctionmethod integrated in infrared camera and etc. Then the scheme of daytime starobservation was designed, the experimental system was set up, the experiment wasaccomplished and sevral infrared star maps were collected. Through the experiment, theeffectiveness of scheme and denoising methods were confirmed.
After star point target imaging, for the single-point-noise, the denoising algorithmsbased on4neighborhood and column direction scanning were proposed. For the stripe- noise, the algorithms based on column histogram offset correction (CHOC) and colummean offset correction (CMOC) were proposed. When the algorithms were used to thestar maps collected in out-field experiment, the results showed that the quality of starmaps was improved largely and the star point target peak signal-noise-ratio (PSNR) wasraised to nearly2times after denoising single-point-noise and stripe-noise.
To increase the star and background contrast ratio furtherly, sevral backgroundfiltering algorithms were analyzed. On the basis of experimental analysis, a composedfiltering algorithm wiener2_top-hat, which was suitable for infrared star map, wasproposed. We added the simulated ideal star map to the observed star map to make up acomposed star map, and use the composed star map to confirm the effectiveness ofdenoising algorithms, the star-point target PSNR and offset error of star-point centroidwere analyzed. The result showed that, after the serial denosing processing, the Psnrwas raised to3~4times of the raw star map, and the offset error of star-point centroid isonly1/30pixel, the accuracy of the algorithms in the paper is high.
The thesis did an in-depth study on the denoising methods for infrared star pointtarget imaging system. The characteristics and denosing methods were analyzed, andspecific ideas and schematics were put forward, the result of out-field experiment andexperiment of processing to star map showed good results, which laid a foundation forinfrared daytime star observation.
本文围绕近红外星点目标成像系统中的一项关键技术——噪声抑制方法展开研究。对星点目标成像前和成像后两个阶段噪声的抑制方法进行了深入的研究,对于解决白天星敏感器中的关键问题具有重要意义。
在星点目标成像前,对低噪声红外成像电路设计技术进行了研究。在理论分析的基础上,进行了低噪声CCD驱动电路和噪声抑制电路的设计,完成了CCD星相机的设计和室内成像实验。研究了红外星相机的噪声抑制技术,包括低噪声驱动电路、信号获取电路和制冷电路的设计技术、相机自带两点法非均匀性校正方法等。然后设计了外场观星试验方案,搭建了试验系统,完成了白天观星试验,采集了大量的红外星图,验证了试验方案的可行性和噪声抑制措施的有效性。
星点目标成像后,针对红外星图中的单点噪声,提出了基于4领域和基于列向量扫描的单点噪声抑制方法;针对红外星图中的条纹噪声,提出了列直方图偏移校正(CHOC)和列均值偏移校正(CMOC)两种算法。并用外场实拍星图完成了对上述算法噪声抑制效果的验证,结果显示,去除单点噪声和条纹噪声后,星图质量得到了较大的改善,星图的星点目标峰值信噪比提高了近2倍。
为进一步提高星点背景对比度,本文研究了多种背景滤波算法,在实验分析的基础上提出了一种适用于红外星图的wiener2_top-hat组合滤波方法。用模拟理想星图与外场观测星图叠加构成合成星图的方法,对文中算法的滤波效果进行验证,分析了星点目标峰值信噪比的变化和星点质心的偏移误差。分析的结果表明:文中序列算法处理后星图的峰值信噪比提高到了原始星图的3~4倍,星点质心偏移仅为1/30像素,算法具有较高的精度。
本文围绕近红外星点目标成像系统的噪声抑制方法展开研究。分析了系统中各种噪声的特性和抑制方法,提出了具有针对性的解决思路和方案,在外场试验和星图处理实验中取得了良好的效果,为进一步开展近红外白天观星试验研究奠定了基础。
Daytime star sensor technology is an important development direction of starsensor technology. The research on daytime star sensor technology is the premise andfoundation of extending the application platform of present star sensor to airborne,shipborne, missileborne and other platforms. Using the stars as the detecting targets,researching infrared imaging systems and launching daytime star observationexperiments is one effective scheme and technical approach of daytime star sensortechnology research.
The thesis did research around the denoising methods, which was one keytechnology of infrared star point target imaging system. The thesis made intensive studyon denoising methods in two sections: before and after star point target imaging, whichwas of great significance in resolving the key problems of daytime star sensor.
Before the star point target imaging, the technology of designing low noise infraredimaging circuits was researched. On the basis of theoretical analysis, a low noise CCDdriving circuit and a denoising circuit were designed, a CCD star camera was designedand an inroom imaging experiment was accomplished. Denoising methods for infraredstar camera were researched, which contain the design technique of low noise drivingcircuit, signal acquisition circuit, cooling circuit, two-piont nonuniformity correctionmethod integrated in infrared camera and etc. Then the scheme of daytime starobservation was designed, the experimental system was set up, the experiment wasaccomplished and sevral infrared star maps were collected. Through the experiment, theeffectiveness of scheme and denoising methods were confirmed.
After star point target imaging, for the single-point-noise, the denoising algorithmsbased on4neighborhood and column direction scanning were proposed. For the stripe- noise, the algorithms based on column histogram offset correction (CHOC) and colummean offset correction (CMOC) were proposed. When the algorithms were used to thestar maps collected in out-field experiment, the results showed that the quality of starmaps was improved largely and the star point target peak signal-noise-ratio (PSNR) wasraised to nearly2times after denoising single-point-noise and stripe-noise.
To increase the star and background contrast ratio furtherly, sevral backgroundfiltering algorithms were analyzed. On the basis of experimental analysis, a composedfiltering algorithm wiener2_top-hat, which was suitable for infrared star map, wasproposed. We added the simulated ideal star map to the observed star map to make up acomposed star map, and use the composed star map to confirm the effectiveness ofdenoising algorithms, the star-point target PSNR and offset error of star-point centroidwere analyzed. The result showed that, after the serial denosing processing, the Psnrwas raised to3~4times of the raw star map, and the offset error of star-point centroid isonly1/30pixel, the accuracy of the algorithms in the paper is high.
The thesis did an in-depth study on the denoising methods for infrared star pointtarget imaging system. The characteristics and denosing methods were analyzed, andspecific ideas and schematics were put forward, the result of out-field experiment andexperiment of processing to star map showed good results, which laid a foundation forinfrared daytime star observation.
引文
[1]刘朝山,刘光斌,王新国等.弹载星敏感器原理及系统应用[M].北京:国防工业出版社,2010:35-65
[2]刘垒,张路,郑辛等.星敏感器技术研究现状及发展趋势[J].红外与激光工程,2007,36(S):529-533
[3]于开峰,吴德伟,戚君宜.天文导航技术的军事应用及发展[J].国防技术基础,2006,7:26-28
[4] Kurt L.Dietz,Brian D.Ramsey,Cheryl D.Alexander,et al.Daytime aspect camera for balloonaltitudes[J].Opt.Eng.2002,41(10):2641-2651
[5] Marie Rex,Edward Chapin,Mark J.Devlin et al.BLAST Autonomous Daytime StarCameras[J].SPIE,2006,6269(62693H)
[6] Eobert B. whitman.Astroinertial Navigation For Cruise Application[R]: California: NorthropCorporation,1977
[7] http://www.northropgrumman.com/Capabilities/LN120G/StellarI-nertial-NavigationSystem/Documents/ln120g.pdf
[8]何炬.国外天文导航技术发展综述[J].舰船科学技术,2005,27(5):91-96
[9]朱耆祥.白天用CCD摄像机对天体目标的探测及实验[J].光电工程,1995,22(5):1-10
[10]王伟国.空间目标白天光电探测技术研究[D].中国科学院长春光学精密机械与物理研究所博士论文,2005
[11]王天聪.航空导航白天星敏感器技术研究及光学系统优化设计[D].长春:中国科学院长春光学精密机械与物理研究所博士论文,2012
[12]钟兴,贾继强,金光等.机载导航白天星敏感器的探测性能及总体设计[J].光学精密工程,2011,19(12):2090-2096
[13]魏合理,陈秀红,余凯等.白天CCD摄像机对天体目标的探测及实验[J].强激光与粒子束,2007,19(2):187-192
[14]徐维安.光谱滤波装置在白天测星中的应用[J].光学精密工程,1996,4(4):84-88
[15]邹江威.强背景弱目标光电检测技术研究[D].长沙:国防科技大学研究生院学位论文,2004
[16]谭碧涛,景春元,王宝国等.光谱滤波技术对星等测量精度的影响[J].强激光与粒子束,2009,21(2):221-224
[17]续敏,王建立,陈涛.短波红外用于白天卫星探测的研究[J].光学技术,2008,34(2):277-280
[18]孙晓兵,洪津,骆冬根等.白天天体光谱偏振成像技术及实验研究[J].大气与环境光学学报,2007,2(6):499-504
[19]万敏,苏毅,杨锐等.提高白天观测星体信噪比的方法研究[J].强激光与粒子束,2003,15(12):1151-1154
[20]梁娟.短波红外昼光恒星成像光学系统设计[J].光学与光电技术,2010,8(2):35-38
[21]全伟,刘百奇,宫晓琳等.惯性/天文/卫星组合导航技术[M].北京:国防工业出版社,2011
[22]魏伟,刘恩海,郑中印.CCD相机视频处理电路设计[J].2012,39(6):144-150
[23]米本和也.CCD/CMOS图像传感器基础与应用[M].北京:科学出版社.2005
[24]刘贤德.CCD及其应用原理.华中理工大学出版社[M].1990
[25]许秀贞,李自田,薛利军.CCD噪声分析及处理技术[J].红外与激光工程,2004,33(4):343-346
[26]王文华,何斌,韩双丽.星上CCD成像非均匀性的实时校正[J].光学精密工程,2010,18(6):1420-1428
[27]佟首峰,阮锦,郝志航.CCD图像传感器降噪技术的研究[J].光学精密工程,2000,8(2):140-144.
[28]陈智,邱跃洪等.CCD观测相机视频处理电路的设计[J].光电技术应用,2009,24(4):54-57
[29]蔡荣太,王延杰.CCD成像传感器的降噪技术[J].2007,28(5):607-612
[30] Texas Instruments Inc.VSP2270Datasheet,2001,http://www.ti.com
[31] Site Mo,Qi Liu.Adaptive Optimization Algorithm for CDS Control Parameters of High-speenCCD[J].SPIE,2010,7658
[32]李云飞,李敏杰,司国良,郭永飞.TDI-CCD图像传感器的噪声分析与处理[J].光学精密工程,2007,15(8):1199-1201.
[33]刘吉,王小燕,李仰军.光电探测技术与应用[M].北京:国防工业出版社,2009
[34]陈维真,周晓东,张春华.基于探测器噪声分析的红外图像增强算法[J].红外与激光工程,2008,37(S):629-634
[35]郭瑞萍,李静,孙葆森.国外红外探测器材料技术新进展[J].兵器材料科学与工程,2009,32(3):98-101
[36]蔡毅,胡旭.红外成像寻的用红外探测器现状和发展趋势[J].红外与激光工程,2006,35(1):7-11
[37]孙再龙,刘会通.红外成像制导对探测器的需求[J].红外与激光工程,2008,37(30):377-381
[38]唐恒敬,吕衍秋,张可峰等.空间遥感用InGaAs短波红外探测[J].光电探测,2007,44(5):42-49
[39]黄杨程.空间遥感用InGaAs短波红外探测[J].红外,2004(3):10-19
[40]江文杰,施建华.光电技术[M].北京:科学出版社,2009
[41] GB/T17444.红外焦平面阵列特性参数测试技术规范[S],1998.
[42]刑素霞.红外热成像与信号处理[M].北京:国防工业出版社,2011
[43]代少升.红外焦平面阵列实时非均匀性校正研究[D].重庆:重庆大学,2004
[44]赵桂芳.红外焦平面阵列探测器关键技术研究[D].西安:西北工业大学,2007
[45] Y.Tendero,J.Gilles.ADMIRE:a locally adaptive single-image,non-uniformity correction anddenoising algorithm:application to uncooled IR camera[J].Proc. SPIE.2012,8353
[46]刑素霞.非制冷红外热图像处理技术研究[D].南京:南京理工大学,2005
[47]仲伟国.非制冷红外热像图像处理技术研究[D].南京:南京理工大学,2007
[48]石岩,张天序,李辉,等.一种考虑红外焦平面器件非线性响应的非均匀性校正方法.红外与毫米波学报,2004,23(4):251—256.
[49]姜光,周慧鑫,王炳建等.基于场景运动分析的红外图像非均匀性校正[J].西安电子科技大学学报(自然科学版),2003,30(1):81-84
[50]牛照东,王卫华,姜卫东等.场景统计类红外图像非均匀性校正算法研究[J].红外与激光工程,2005,34(3):261-265
[51]李旭,杨虎.基于两点的红外图像非均线校正算法应用[J].红外与激光工程,2008,37(S):608-610
[52]刘爽,冯林,赵凯生等.一种红外图像非均匀性校正新方法的DSP实现[J].仪器仪表学报,2008,29(5):1096-1099
[53]代少升,袁祥辉.红外图像非均匀性实时校正的新技术[J].光学精密工程,2004,12(2):201-204
[54]王钰,陈钱,殷德奎等.实时红外图像非均匀性校正技术研究[J].红外与毫米波学报,1999,18(2):151-155
[55]周建勇,唐尊烈,蒋志伟.基于FPGA红外图像实时非均匀性校正及滤波技术[J].红外与激光工程,2006,35(S):393-396
[56]周建勋,王利平,刘滨.红外图像非均匀性产生分析[J].红外与激光工程,1997,26(3):11-13
[57] GB/T17444.1998.红外焦平面阵列特性参数测试技术规范
[58]周慧鑫,殷世民,刘上乾等.红外焦平面器件盲元检测及补偿算法[J].光子学报,2004,33(5):598-560
[59] Dieickx B.Meynants G.Missing pixels correction algorithm for imager sensor.SPIE,1998,3410
[60]张广军.星图识别[M].北京:国防工业出版社,2011
[61]陈秀红,魏合理,余凯等.星敏感器白天观星的对比度分析[J].大气与环境光学学报,2008,3(1):28-35
[62]王一凡,李零印.白天观测空间目标的恒星光电探测系统的杂散光抑制[J].光学精密工程,2011,19(12):2954-2811
[63] FTT1010-M Frame Transfer CCD Image Sensor Datasheet. PHILIPS.1999
[64] FTF402711M Full-Frame CCD Image Sensor. DALSA.2004
[65] Frame Transfer CCD Image Sensor TH7890M Datasheet.2003
[66] EV76C5601.3Mpixels B&W and Color CMOS Image Sensor Datasheet. E2V.2009
[67]陈学飞.面阵CCD成像系统外围电路设计[D].西安:中国科学院西安光学精密机械研究所,2007
[68]金龙旭,李国宁,刘妍妍.帧转移型面阵CCD驱动电路的设计[J].光学精密工程,2008,16(6):1140-1145
[69]张闻文,陈钱.电子倍增CCD噪音特性研究[J].光子学报,2009,38(4):756-760
[70] Zdenek Barton,Radimir Vrba.CCD image sensor degradation by X-ray radiation[J].IEEE,2005
[71]王世峰,赵馨,佟首峰等.CCD输出信号处理电路的研究[J].红外与激光工程,2007,36(S):311-313
[72]张健.CCD信号处理的滤波器设计[J].航天返回与遥感,2006,27(4):49-52
[73]尹亮.CCD智能相机图像采集硬件平台的研究[D].哈尔滨:哈尔滨工程大学,2008
[74] EL7457Datasheet.Intersil.2005
[75]严志刚,蒋德中,段然.高分辨率CCD模拟前端系统设计[J].航天控制,2010,28(2):89-92
[76]郑亮亮,金光,张刘.高频高信噪比CCD图像采集系统的研究[J].微计算机信息,2010,26(6-2):192-194
[77]王书宏,胡谋法,陈曾平.天文CCD相机的噪声分析与信噪比模型的研究[J].半导体光电,2007,,28(5):731-734
[78]王华,汶德胜,邱跃洪等.天文观测CCD相机低噪声CCD视频处理电路的分析与设计[J].光学技术,2007,33(1):48-52
[79]韦韧.星载科学试验用CCD相机设计与实现[D].北京:中国科学院空间科学与应用研究中心,2010
[80]王帅.CCD器件的特性评价及其驱动和数据采集电路设计[D].杭州:浙江大学,2006
[81]杜琳琳.空间目标观测科学级CCD相机实现技术研究[D].长沙:国防科技大学,2005
[82]张明涛,刘强,王跃明等.低噪声小型化焦平面驱动与信息获取系统设计[J].红外技术,2008,30(11):633-637
[83]徐隆,易建新.128*128红外焦平面阵列时序分析与温控电路设计[J].红外与毫米波学报,2003,22(4):261-264
[84]吴和然,周云,张宇等.非制冷红外探测器低噪声驱动和处理电路的设计研究[J].红外技术,2011,33(9):505-508
[85]张沛,祝红彬,吕坚等.低噪声非制冷红外焦平面阵列驱动电路的设计[J].红外与激光工程,2010,39(5):806-810
[86]卫翠玉.HgCdTe红外探测器放大电路的低噪声设计[J].微计算机信息,2009,25(6-2):276-248
[87]王明富.电子倍增CCD驱动技术及其噪声特性研[D].成都:中国科学院光电技术研究所,2011
[88]郑兴,蒋亚东,罗凤武等.基于ADN8830的非制冷红外焦平面温度控制电路设计[J].现代电子技术,2010
[89] Thermoelectric Cooler Controller ADN8830Datasheet.2012
[90]樊巧云,张广军.离散噪声图像的光斑质心算法及其硬件实现[J].光学精密工程,2011,19(12):2992-2997
[91]杨清珍.星图实时预处理方法研究及实现[D].武汉:华中科技大学,2005
[92]王晓甜.基于信噪特征的遥感图像去噪方法研究[D].西安:西安电子科技大学,2011
[93]任建乐,陈钱,钱惟贤.基于配准的红外焦平面阵列条纹校正[J].红外与毫米波学报,2011,30(6):499-503
[94] Weixian Qian,Qian Chen,Junqi Bai etal.Adaptive convergence nonuniformity correctionalgorithm[J].APPLIED OPTICS,2011,50(1):1-10
[95]白俊奇,陈钱,钱惟贤.红外凝视成像系统中的CDS噪声抑制技术研究[J].中国图形图像学报,2010,15(7):1062-1066
[96] Weixian Qian,Qian Chen,Guohua Gu etal.Correction method for stripe nonuniformity [J].APPLIED OPTICS,2010,49(10):1764-1773
[97] Weixian Qian,Qian Chen,Guohua Gu.Minmum mean square error method for stripenonuniformity correction [J].CHINESE OPTICS LETTERS,2011,9(5)
[98]邹前进,冯亮,汪亚.红外图像空间噪声分析和预处理方法改进[J].应用光学,2007,28(4):426-430
[99]张飞,李承芳.红外背景抑制与弱小目标的检测算法[J].光学技术,2004,30(3):337-340
[100] Charlene E C,Jerry S.Optimization of point target tracking filters[J],IEEE Transactions onAerospace and Electronic Systems,2000,36(1):5-25
[101]于天河,郝富春,康为民等.红外图像增强技术综述[J].红外与激光工程,2007,36(S):335-338
[102]林长青,李建林,孙胜利等.含弱小目标大视场红外图像复杂背景抑制的实现[J].科学技术与工程,2007,7(14):3399-3403
[103]蔡智富,赵坤,杨莘元.基于DSP与FPGA的红外起伏背景估计系统[J].应用科技,200633(8):34-36
[104]金阿立,王永仲.基于局部自适应中值滤波的红外背景抑制方法[J].红外技术,2007,29(8):452-454
[105] Rafael C. Gonzalez,Richard E. Woods.阮秋琦,阮宇智等译.数字图像处理[M].北京:电子工业出版社,2008
[106] Rafael C. Gonzalez,Richard E. Woods.阮秋琦,阮宇智等译.数字图像处理(Matlab版)[M].北京:电子工业出版社,2008
[107]闵君,邓晓.目标与背景的红外特征研究综述[J].红外与激光工程,2006,3(5S):385-388
[108]聂洪山,沈振康.一种基于Wiener滤波的红外背景抑制方法[J].国防科技大学学报,2003,25(3):54-57
[109]吴超,安伟,龙云利等.远距离红外图像目标分析及背景抑制算法[J].红外技术,2008,30(10):571-574
[110]杨莘元,蔡智富,赵洁.自适应背景技术在红外起伏背景估计的应用[J].弹箭与制导学报,2004,24(3):24-27
[111] Vladimir V. Lukin,Dmitriy V. Fevralev,Nikolay N. Ponomarenko,etal.Discrete cosinetransform-based local adaptive filtering of images corrupted by nonstationary noise[J].Journalof Electronic Imaging,2010,19(2)
[112] Tianxu Zhang,Yan Shi.Edge-directed adaptive nonuniformity correction for staringinfrared focal plane arrays[J].Optical Engineering,2006,45(1)
[113]张辉,袁家虎,刘恩海.CCD噪声对星敏感器星点定位精度的影响[J].红外与激光工程,2006,35(5):629-633
[114]王进,张辉,林玲等.基于星敏感器的卫星对地定姿误差分析[J].计算机仿真,2012,29(8):68-71
[115]张辉,钟建勇,袁家虎等.电路噪声对星敏感器星点定位精度的影响[J].光学精密工程2006,14(7):1052-1056
[116]侯和坤,张新.红外焦平面阵列非均匀性校正技术的最新进展[J].红外与激光工程,2004,33(1):79-82
[2]刘垒,张路,郑辛等.星敏感器技术研究现状及发展趋势[J].红外与激光工程,2007,36(S):529-533
[3]于开峰,吴德伟,戚君宜.天文导航技术的军事应用及发展[J].国防技术基础,2006,7:26-28
[4] Kurt L.Dietz,Brian D.Ramsey,Cheryl D.Alexander,et al.Daytime aspect camera for balloonaltitudes[J].Opt.Eng.2002,41(10):2641-2651
[5] Marie Rex,Edward Chapin,Mark J.Devlin et al.BLAST Autonomous Daytime StarCameras[J].SPIE,2006,6269(62693H)
[6] Eobert B. whitman.Astroinertial Navigation For Cruise Application[R]: California: NorthropCorporation,1977
[7] http://www.northropgrumman.com/Capabilities/LN120G/StellarI-nertial-NavigationSystem/Documents/ln120g.pdf
[8]何炬.国外天文导航技术发展综述[J].舰船科学技术,2005,27(5):91-96
[9]朱耆祥.白天用CCD摄像机对天体目标的探测及实验[J].光电工程,1995,22(5):1-10
[10]王伟国.空间目标白天光电探测技术研究[D].中国科学院长春光学精密机械与物理研究所博士论文,2005
[11]王天聪.航空导航白天星敏感器技术研究及光学系统优化设计[D].长春:中国科学院长春光学精密机械与物理研究所博士论文,2012
[12]钟兴,贾继强,金光等.机载导航白天星敏感器的探测性能及总体设计[J].光学精密工程,2011,19(12):2090-2096
[13]魏合理,陈秀红,余凯等.白天CCD摄像机对天体目标的探测及实验[J].强激光与粒子束,2007,19(2):187-192
[14]徐维安.光谱滤波装置在白天测星中的应用[J].光学精密工程,1996,4(4):84-88
[15]邹江威.强背景弱目标光电检测技术研究[D].长沙:国防科技大学研究生院学位论文,2004
[16]谭碧涛,景春元,王宝国等.光谱滤波技术对星等测量精度的影响[J].强激光与粒子束,2009,21(2):221-224
[17]续敏,王建立,陈涛.短波红外用于白天卫星探测的研究[J].光学技术,2008,34(2):277-280
[18]孙晓兵,洪津,骆冬根等.白天天体光谱偏振成像技术及实验研究[J].大气与环境光学学报,2007,2(6):499-504
[19]万敏,苏毅,杨锐等.提高白天观测星体信噪比的方法研究[J].强激光与粒子束,2003,15(12):1151-1154
[20]梁娟.短波红外昼光恒星成像光学系统设计[J].光学与光电技术,2010,8(2):35-38
[21]全伟,刘百奇,宫晓琳等.惯性/天文/卫星组合导航技术[M].北京:国防工业出版社,2011
[22]魏伟,刘恩海,郑中印.CCD相机视频处理电路设计[J].2012,39(6):144-150
[23]米本和也.CCD/CMOS图像传感器基础与应用[M].北京:科学出版社.2005
[24]刘贤德.CCD及其应用原理.华中理工大学出版社[M].1990
[25]许秀贞,李自田,薛利军.CCD噪声分析及处理技术[J].红外与激光工程,2004,33(4):343-346
[26]王文华,何斌,韩双丽.星上CCD成像非均匀性的实时校正[J].光学精密工程,2010,18(6):1420-1428
[27]佟首峰,阮锦,郝志航.CCD图像传感器降噪技术的研究[J].光学精密工程,2000,8(2):140-144.
[28]陈智,邱跃洪等.CCD观测相机视频处理电路的设计[J].光电技术应用,2009,24(4):54-57
[29]蔡荣太,王延杰.CCD成像传感器的降噪技术[J].2007,28(5):607-612
[30] Texas Instruments Inc.VSP2270Datasheet,2001,http://www.ti.com
[31] Site Mo,Qi Liu.Adaptive Optimization Algorithm for CDS Control Parameters of High-speenCCD[J].SPIE,2010,7658
[32]李云飞,李敏杰,司国良,郭永飞.TDI-CCD图像传感器的噪声分析与处理[J].光学精密工程,2007,15(8):1199-1201.
[33]刘吉,王小燕,李仰军.光电探测技术与应用[M].北京:国防工业出版社,2009
[34]陈维真,周晓东,张春华.基于探测器噪声分析的红外图像增强算法[J].红外与激光工程,2008,37(S):629-634
[35]郭瑞萍,李静,孙葆森.国外红外探测器材料技术新进展[J].兵器材料科学与工程,2009,32(3):98-101
[36]蔡毅,胡旭.红外成像寻的用红外探测器现状和发展趋势[J].红外与激光工程,2006,35(1):7-11
[37]孙再龙,刘会通.红外成像制导对探测器的需求[J].红外与激光工程,2008,37(30):377-381
[38]唐恒敬,吕衍秋,张可峰等.空间遥感用InGaAs短波红外探测[J].光电探测,2007,44(5):42-49
[39]黄杨程.空间遥感用InGaAs短波红外探测[J].红外,2004(3):10-19
[40]江文杰,施建华.光电技术[M].北京:科学出版社,2009
[41] GB/T17444.红外焦平面阵列特性参数测试技术规范[S],1998.
[42]刑素霞.红外热成像与信号处理[M].北京:国防工业出版社,2011
[43]代少升.红外焦平面阵列实时非均匀性校正研究[D].重庆:重庆大学,2004
[44]赵桂芳.红外焦平面阵列探测器关键技术研究[D].西安:西北工业大学,2007
[45] Y.Tendero,J.Gilles.ADMIRE:a locally adaptive single-image,non-uniformity correction anddenoising algorithm:application to uncooled IR camera[J].Proc. SPIE.2012,8353
[46]刑素霞.非制冷红外热图像处理技术研究[D].南京:南京理工大学,2005
[47]仲伟国.非制冷红外热像图像处理技术研究[D].南京:南京理工大学,2007
[48]石岩,张天序,李辉,等.一种考虑红外焦平面器件非线性响应的非均匀性校正方法.红外与毫米波学报,2004,23(4):251—256.
[49]姜光,周慧鑫,王炳建等.基于场景运动分析的红外图像非均匀性校正[J].西安电子科技大学学报(自然科学版),2003,30(1):81-84
[50]牛照东,王卫华,姜卫东等.场景统计类红外图像非均匀性校正算法研究[J].红外与激光工程,2005,34(3):261-265
[51]李旭,杨虎.基于两点的红外图像非均线校正算法应用[J].红外与激光工程,2008,37(S):608-610
[52]刘爽,冯林,赵凯生等.一种红外图像非均匀性校正新方法的DSP实现[J].仪器仪表学报,2008,29(5):1096-1099
[53]代少升,袁祥辉.红外图像非均匀性实时校正的新技术[J].光学精密工程,2004,12(2):201-204
[54]王钰,陈钱,殷德奎等.实时红外图像非均匀性校正技术研究[J].红外与毫米波学报,1999,18(2):151-155
[55]周建勇,唐尊烈,蒋志伟.基于FPGA红外图像实时非均匀性校正及滤波技术[J].红外与激光工程,2006,35(S):393-396
[56]周建勋,王利平,刘滨.红外图像非均匀性产生分析[J].红外与激光工程,1997,26(3):11-13
[57] GB/T17444.1998.红外焦平面阵列特性参数测试技术规范
[58]周慧鑫,殷世民,刘上乾等.红外焦平面器件盲元检测及补偿算法[J].光子学报,2004,33(5):598-560
[59] Dieickx B.Meynants G.Missing pixels correction algorithm for imager sensor.SPIE,1998,3410
[60]张广军.星图识别[M].北京:国防工业出版社,2011
[61]陈秀红,魏合理,余凯等.星敏感器白天观星的对比度分析[J].大气与环境光学学报,2008,3(1):28-35
[62]王一凡,李零印.白天观测空间目标的恒星光电探测系统的杂散光抑制[J].光学精密工程,2011,19(12):2954-2811
[63] FTT1010-M Frame Transfer CCD Image Sensor Datasheet. PHILIPS.1999
[64] FTF402711M Full-Frame CCD Image Sensor. DALSA.2004
[65] Frame Transfer CCD Image Sensor TH7890M Datasheet.2003
[66] EV76C5601.3Mpixels B&W and Color CMOS Image Sensor Datasheet. E2V.2009
[67]陈学飞.面阵CCD成像系统外围电路设计[D].西安:中国科学院西安光学精密机械研究所,2007
[68]金龙旭,李国宁,刘妍妍.帧转移型面阵CCD驱动电路的设计[J].光学精密工程,2008,16(6):1140-1145
[69]张闻文,陈钱.电子倍增CCD噪音特性研究[J].光子学报,2009,38(4):756-760
[70] Zdenek Barton,Radimir Vrba.CCD image sensor degradation by X-ray radiation[J].IEEE,2005
[71]王世峰,赵馨,佟首峰等.CCD输出信号处理电路的研究[J].红外与激光工程,2007,36(S):311-313
[72]张健.CCD信号处理的滤波器设计[J].航天返回与遥感,2006,27(4):49-52
[73]尹亮.CCD智能相机图像采集硬件平台的研究[D].哈尔滨:哈尔滨工程大学,2008
[74] EL7457Datasheet.Intersil.2005
[75]严志刚,蒋德中,段然.高分辨率CCD模拟前端系统设计[J].航天控制,2010,28(2):89-92
[76]郑亮亮,金光,张刘.高频高信噪比CCD图像采集系统的研究[J].微计算机信息,2010,26(6-2):192-194
[77]王书宏,胡谋法,陈曾平.天文CCD相机的噪声分析与信噪比模型的研究[J].半导体光电,2007,,28(5):731-734
[78]王华,汶德胜,邱跃洪等.天文观测CCD相机低噪声CCD视频处理电路的分析与设计[J].光学技术,2007,33(1):48-52
[79]韦韧.星载科学试验用CCD相机设计与实现[D].北京:中国科学院空间科学与应用研究中心,2010
[80]王帅.CCD器件的特性评价及其驱动和数据采集电路设计[D].杭州:浙江大学,2006
[81]杜琳琳.空间目标观测科学级CCD相机实现技术研究[D].长沙:国防科技大学,2005
[82]张明涛,刘强,王跃明等.低噪声小型化焦平面驱动与信息获取系统设计[J].红外技术,2008,30(11):633-637
[83]徐隆,易建新.128*128红外焦平面阵列时序分析与温控电路设计[J].红外与毫米波学报,2003,22(4):261-264
[84]吴和然,周云,张宇等.非制冷红外探测器低噪声驱动和处理电路的设计研究[J].红外技术,2011,33(9):505-508
[85]张沛,祝红彬,吕坚等.低噪声非制冷红外焦平面阵列驱动电路的设计[J].红外与激光工程,2010,39(5):806-810
[86]卫翠玉.HgCdTe红外探测器放大电路的低噪声设计[J].微计算机信息,2009,25(6-2):276-248
[87]王明富.电子倍增CCD驱动技术及其噪声特性研[D].成都:中国科学院光电技术研究所,2011
[88]郑兴,蒋亚东,罗凤武等.基于ADN8830的非制冷红外焦平面温度控制电路设计[J].现代电子技术,2010
[89] Thermoelectric Cooler Controller ADN8830Datasheet.2012
[90]樊巧云,张广军.离散噪声图像的光斑质心算法及其硬件实现[J].光学精密工程,2011,19(12):2992-2997
[91]杨清珍.星图实时预处理方法研究及实现[D].武汉:华中科技大学,2005
[92]王晓甜.基于信噪特征的遥感图像去噪方法研究[D].西安:西安电子科技大学,2011
[93]任建乐,陈钱,钱惟贤.基于配准的红外焦平面阵列条纹校正[J].红外与毫米波学报,2011,30(6):499-503
[94] Weixian Qian,Qian Chen,Junqi Bai etal.Adaptive convergence nonuniformity correctionalgorithm[J].APPLIED OPTICS,2011,50(1):1-10
[95]白俊奇,陈钱,钱惟贤.红外凝视成像系统中的CDS噪声抑制技术研究[J].中国图形图像学报,2010,15(7):1062-1066
[96] Weixian Qian,Qian Chen,Guohua Gu etal.Correction method for stripe nonuniformity [J].APPLIED OPTICS,2010,49(10):1764-1773
[97] Weixian Qian,Qian Chen,Guohua Gu.Minmum mean square error method for stripenonuniformity correction [J].CHINESE OPTICS LETTERS,2011,9(5)
[98]邹前进,冯亮,汪亚.红外图像空间噪声分析和预处理方法改进[J].应用光学,2007,28(4):426-430
[99]张飞,李承芳.红外背景抑制与弱小目标的检测算法[J].光学技术,2004,30(3):337-340
[100] Charlene E C,Jerry S.Optimization of point target tracking filters[J],IEEE Transactions onAerospace and Electronic Systems,2000,36(1):5-25
[101]于天河,郝富春,康为民等.红外图像增强技术综述[J].红外与激光工程,2007,36(S):335-338
[102]林长青,李建林,孙胜利等.含弱小目标大视场红外图像复杂背景抑制的实现[J].科学技术与工程,2007,7(14):3399-3403
[103]蔡智富,赵坤,杨莘元.基于DSP与FPGA的红外起伏背景估计系统[J].应用科技,200633(8):34-36
[104]金阿立,王永仲.基于局部自适应中值滤波的红外背景抑制方法[J].红外技术,2007,29(8):452-454
[105] Rafael C. Gonzalez,Richard E. Woods.阮秋琦,阮宇智等译.数字图像处理[M].北京:电子工业出版社,2008
[106] Rafael C. Gonzalez,Richard E. Woods.阮秋琦,阮宇智等译.数字图像处理(Matlab版)[M].北京:电子工业出版社,2008
[107]闵君,邓晓.目标与背景的红外特征研究综述[J].红外与激光工程,2006,3(5S):385-388
[108]聂洪山,沈振康.一种基于Wiener滤波的红外背景抑制方法[J].国防科技大学学报,2003,25(3):54-57
[109]吴超,安伟,龙云利等.远距离红外图像目标分析及背景抑制算法[J].红外技术,2008,30(10):571-574
[110]杨莘元,蔡智富,赵洁.自适应背景技术在红外起伏背景估计的应用[J].弹箭与制导学报,2004,24(3):24-27
[111] Vladimir V. Lukin,Dmitriy V. Fevralev,Nikolay N. Ponomarenko,etal.Discrete cosinetransform-based local adaptive filtering of images corrupted by nonstationary noise[J].Journalof Electronic Imaging,2010,19(2)
[112] Tianxu Zhang,Yan Shi.Edge-directed adaptive nonuniformity correction for staringinfrared focal plane arrays[J].Optical Engineering,2006,45(1)
[113]张辉,袁家虎,刘恩海.CCD噪声对星敏感器星点定位精度的影响[J].红外与激光工程,2006,35(5):629-633
[114]王进,张辉,林玲等.基于星敏感器的卫星对地定姿误差分析[J].计算机仿真,2012,29(8):68-71
[115]张辉,钟建勇,袁家虎等.电路噪声对星敏感器星点定位精度的影响[J].光学精密工程2006,14(7):1052-1056
[116]侯和坤,张新.红外焦平面阵列非均匀性校正技术的最新进展[J].红外与激光工程,2004,33(1):79-82