基于纹理特征多分辨双Markov-GAR模型的SAR图像分割

为了提高SAR图像分割精度,提出在以灰度共生矩阵产生的纹理统计量为特征所生成的图像上,同时考虑SAR图像像素间空间分布特征和局部灰度均值和方差等统计量给出多分辨双Markov框架下的GAR模型,采用多分辨MPM的参数估计方法及对应的无监督分割算法,对SAR图像进行纹理分割。实验结果表明该方法用于一些高分辨SAR图像,与基于灰度图像上的多分辨双Markov-GAR模型纹理分割相比,在分割精度上能降低分割时的错分率。     

星载合成孔径雷达的辐射校准

星载合成孔径雷达（ＳＡＲ）的辐射校准用于从ＳＡＲ图像演绎出雷达后向散射系数σ°。着重从端到端系统的角度阐述辐射校准原理；详细介绍内部校准和外部校准过程，并给出若干实例；还对校准误差源进行了较深入的讨论。     

一种检测ＳＡＲ图像边缘的方法

传统算法不能很好地解决合成孔径雷达（ＳＡＲ）图像边缘检测问题，为此提出了一种改进方法：将Ｈaralick曲面拟合法和改进的广义模糊算子（ＧＦＯ）两种算法相结合，分别独立求出ＳＡＲ图像边缘，然后将分别求出的图像边缘合并，得出最终边缘，用实际ＳＡＲ图像对该算法进行检验，验证了该算法的有效性。     

彩色图像中的本征图像的抽取

光源的位置和颜色影响到景物在摄像机中的成像,高光(highlight)的出现使一般的分割算法得不到理想的分割结果。文中根据二色反射模型(Dich-romatic Reflectioa Model),将图像分解成两个本征图像(intrinsic image)——本色图像(matte image)和高光图像(highlight image)。本色图像是去掉高光后的图像,反映了景物本身的不变性,不受外部因素(如光源的位置和颜色)的影响。而高光图像是只含有高光的图像,反映了外部因素的影响,有助于确定物体的形状。文中的彩色图像是指单一颜色光照(非单一波长的光照)下的单色物体在彩色CCD 摄像机中成的像。     

卫星干涉高光谱遥感图像序列差值压缩编码

根据干涉高光谱图像的成像特点和卫星遥感图像压缩编码系统要求，提出了一种新的卫星干涉高光谱图像序列压缩算法．新算法利用干涉成像光谱仪推扫成像特点提出了一种低存储量，帧间小波域匹配的图像序列压缩方案，提高图像质量3—4dB．算法首先通过小波域匹配算法检测出相邻图像之间的推扫位移量并移位求得两帧的最佳差值图像，然后对差值图像进行静止图像EBCOT压缩编码，从而提高总体编码效率．该算法具有与单帧图像编码算法相当的复杂度，只需要对当前图像与模板的差值图像进行基于小波变换的编码，避免了目前基于三维小波变换的编码算法对系统大存储量要求以及编码延时大的缺陷．仿真结果表明，本算法针对干涉高光谱图像编码，可获得比基于三维小波变换的算法相当甚至更好的效果，并且大大降低了编码延时．     

惯性/图像组合导航中的双模态双滤波器研究

在简要介绍了飞行器视觉图像定位导航原理及模型的基础上，针对其非线性模型的推广Kalman滤波的收敛与初始条件有关的问题，将其定位导航的两种模型（线性与非线性模型）组合，提出了双模态双滤波器滤波方法。这种滤波能很好地解决非线性推广Kalman滤波的收敛问题。通过第一个线性滤波器的滤波估计给第二个非线性滤波器提供滤波初值，使这一非线性滤波收敛，并能取得较高的滤波精度。     

电视导引头图像闪烁故障分析

针对电视导引头存在的“图像闪烁”故障，重点分析了故障的常发生部位，如硅靶管、CCD、图像处理电路和电视摄像机光圈等，并从故障部位的结构特点和工作原理入手，详细阐述了故障产生的原因、机理以及排故方法，为同类故障的修理提供参考。     

Tomography system for measurement of gas properties in combustion flow field

This paper describes a self-designed fiber-coupled tomography system and its application in combustion diagnostics. The tomographic technique, which combines tunable diode laser spectroscopy and algebraic reconstruction technique, enables the simultaneous reconstruction of temperature and gas concentration with both spatial and temporal resolutions. The system measures a maximum diameter of 35 cm in a circular area with a minimum spatial resolution of 1 mm×1 mm and temporal response of up to 1 kHz. Simulations validate the effects of the beam arrangement and discrete grid on reconstruction accuracy, and give the optimal beam arrangements. Experiments are made to demonstrate the tomography method, and systems are constructed in laboratory and on engineering test benches.     

基于增量学习的高光谱图像目标检测

高光谱图像目标检测是高光谱图像分析中的重要研究内容之一。本文从经典有效的约束能量最小化算法出发,提出了一种基于增量学习的高光谱目标检测方法。当获得新的样本时,不需要重新计算所有样本的自相关矩阵即可对检测器模型进行更新,减轻了星上有限计算资源的负担。实验结果表明:本文提出的目标检测算法在压制背景光谱的同时可以更好地适应目标光谱,提高了算法的检测性能。     

TS-InSAR analysis for monitoring ground deformation in Lanzhou New District,the loess Plateau of China,from 2017 to 2019

Large-scale land creation projects involving the cutting of mountains to infill gullies for construction have been carried out in Lanzhou New District (LZND). However, there is an urgent need for comprehensive and detailed research on the spatiotemporal evolution of ground deformation in LZND. Based on Sentinel-1A SAR data, combined with the urban geological background, the ground deformation in LZND from 2017 to 2019 was analysed. Two independent, multi-temporal techniques, persistent scatterers interferometry (PS-InSAR) and the small baseline subset (SBAS-InSAR), were used to calculate the deformation time series, and the results were cross-verified. The time series-monitoring results of the SBAS and PS calculations exhibited strong consistency in LZND and verified the high reliability of the experimental results. The results showed the whole surface of the LZND from March 2017 to October 2019 maintained stability, and the deformation rate was primarily in the range of ?10 to 10 mm/year. However, ground deformation in the Xicha area was evident. The maximum annual deformation rates monitored by SBAS-InSAR and PS-InSAR were ?52.48 mm/year and ?56.35 mm/year, respectively. The most typical deformation areas include the built-up area and the land creation area. The surface subsidence area was concentrated in the filling area. The ground deformation range of LZND kept expanding and accelerating from 2017 to 2019. Land creation, urban construction, geology and precipitation were the primary factors contributing to local severe ground deformation. The results of this study provide reference for the regional urban planning in LZND.