航空矢量重力测量水平分量的带限直接地形影响

基于第二类Helmert凝聚法的级数展开式,独立推导了航空矢量重力测量水平分量带限直接地形影响的计算公式。在中国西部山区选取了两条沿纬圈方向4000m航线高度上的航线,采用 的数字高程模型基于解析核计算了水平分量的直接地形影响,经低通滤波后与基于带限公式计算的地形影响进行了比较。数值计算结果表明,二者吻合较好,本文给出的带限地形影响公式可用于航空矢量重力测量水平分量的地形归算。     

航空重力测量数据向下延拓中空间协方差函数特性研究

本文通过对航空重力测量数据的分析,建立起具有空间相关特性的空间协方差函数模型。利用所建立的模型,将航空重力测量试验数据采用最小二乘配置的方法向下延拓到地面,与地面已知重力数据进行比较。由比较结果,分析了空间协方差函数模型对航空重力测量数据向下延拓结果的影响,并表明所建立的空间协方差函数模型,满足协方差函数特性,且在局部区域使用能够达到满意的精度要求。     

一种改进的基于坡度变化的机载激光雷达点云滤波方法

机载激光点云数据滤波是获取高精度数字表面模型和数字高程模型的关键。本文分析了几种重要的滤波算法,在研究基于坡度变化的滤波算法的基础上,提出一种改进的分块滤波处理的方法。实验表明:该方法能有效对点云数据进行分类。     

基于纹理特征的围填海SAR图像分水岭分割方法

本文提出了一种基于纹理特征的围填海SAR图像分水岭分割方法,首先对机载MiniSAR图像进行灰度共生矩阵纹理滤波,获得纹理特征图像,再对纹理特征图像进行分水岭算法分割,将获得的形态学重建图像进行门限阈值分割,得到最后的二值化分割结果。该方法一方面通过调整灰度共生矩阵纹理滤波的窗口大小,抑制了斑点噪声的影响;另一方面,利用分水岭算法对边缘模糊杂乱图像的优势,提高了围填海信息提取的准确性。实验结果表明,本方法对高分辨率SAR图像围填海监测图像的分割效果良好。     

利用遥感光谱特征提取岩性信息的基础和技术研究

地物光谱特征的研究是遥感技术的基础研究工作之一．从光谱遥感发展与地质应用的趋势出发。从光谱遥感岩矿识别基础与识别技术方法两方面阐述了光谱遥感的研究进展．在技术方法方面，主要从多光谱与成像光谱以及遥感与航空放射性信息集成3个层次上，分析利用光谱特征进行岩石矿物识别的研究进展及其潜力与可行性，并简单阐述了遥感与航空放射性信息的复合这一遥感岩性信息识别研究的发展趋势．     

航空重力测量中牛顿中心差分器对确定载体加速度的影响

讨论不同点数的牛顿中心差分器对航空重力测量中确定载体加速度的影响。理论分析表明,当航空重力测量的有效频段位于牛顿中心差分器的通带时,不同点数的牛顿中心差分器所得结果经低通滤波后几乎没有差异。实验表明,当采样间隔为1 s、载体平均速度为155 m/s、所需重力数据的分辨率为10 km时,低通滤波后不同点数的牛顿中心差分器输出结果之间的较差优于2.1 mGal。     

高分辨率机载SAR影像判读实验

近年来机载SAR系统在国内得到快速发展。由于SAR系统具有不同于光学传感器的成像机理,因而可以提供全新的数据获取手段和不同的地物信息。利用高分辨率机载SAR影像进行解译时必须熟悉其成像机理和图像信息特点,充分了解SAR图像解译标志的特点和各类地物的解译规律。本文以高分辨率机载SAR数据为基础,对比光学影像,从SAR成像特点和地物散射特性出发,对SAR影像进行了目视解译,分析了SAR影像在地形地物要素识别中的应用潜力。     

机载激光雷达数据滤波和人工编辑

高精度的DTM/DEM是获取基础地理信息数据进行建筑物重建、道路提取、植被分析的重要数据源。机载LiDAR系统的主要任务之一就是解决如何得到高质量的DTM的问题。文中针对机载LiDAR数据滤波和滤波后人工编辑展开研究。由于任何一种滤波算法,都有一定的局限性,从实际应用的角度来说,人工编辑仍然起着重要的作用,因此,研究重点围绕滤波后的人工编辑展开,旨在探求工程应用中高效、快速、准确的DTM获取途径,为工程实践提供技术支持。     

Seasonal variation of airborne fungi of the Tiantishan Grottoes and Western Xia Museum,Wuwei, China

In this study, a systematic survey of cultural airborne fungi was carried out in the occurrence environments of wall paintings that are preserved in the Tiantishan Grottoes and the Western Xia Museum, China. A bio-aerosol sampler was used for sampling in four seasons in 2016. Culture-dependent and -independent methods were taken to acquire airborne fungal concentration and purified strains; by the extraction of genomic DNA, amplification of fungal ITS rRNA gene region, sequencing, and phylogenetic analysis, thereafter the fungal community composition and distribution characteristics of different study sites were clarified. We disclosure the main environmental factors which may be responsible for dynamic changes of airborne fungi at the sampling sites. The concentration of cultural airborne fungi was in a range from 13 to 1,576 CFU/m³, no significant difference between the two sites at the Tiantishan Grottoes, with obvious characteristics of seasonal variation, in winter and spring were higher than in summer and autumn. Also, there was a significant difference in fungal concentration between the inside and outside of the Western Xia Museum, the outside of the museum was far more than the inside of the museum in the four seasons, particularly in the winter. Eight fungal genera were detected, including Cladosporium, Penicillium, Alternaria, and Filobasidium as the dominant groups. The airborne fungal community structures of the Tiantishan Grottoes show a distinct characteristic of seasonal variation and spatial distribution. Relative humidity, temperature and seasonal rainfall influence airborne fungal distribution. Some of the isolated strains have the potential to cause biodeterioration of ancient wall paintings. This study provides supporting information for the pre-warning conservation of cultural relics that are preserved at local sites and inside museums.     

NOAA WP-3D instrumentation and flight operations on AGASP-II

The second Arctic Gas and Aerosol Sampling Program (AGASP-II) was conducted across the non-Soviet Arctic in March and April 1986, to study the aerosol, gaseous, chemical, and optical properties of Arctic haze. One component of the program was supported with an instrumented NOAA WP-3D atmospheric research aircraft. Measurements of wind, temperature, ozone, water vapor, condensation nucleus concentration, and aerosol scattering extinction coefficient were used to determine the locations and properties of haze layers. The first three NOAA WP-3D research flights were conducted north of Barrow, Alaska, and over the Beaufort Sea northeast of Barter Island, Alaska. The next three sampled conditions in the high Arctic near Alert, Northwest Territories, Canada. All basic meteorological, gas, and aerosol systems are described. The WP-3D flight tracks and operations are presented.