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GPS测量中的大气路径延迟订正 总被引:6,自引:1,他引:6
根据上海和北京两站1992~1993两年的气象探空资料,分别计算了GPS伪距测量中的干项和湿项订正值。在此资料样本上,用最小二乘回归拟合得到了干、湿项订正的算式。分析大气球面分层的计算结果可见,干、湿项订正值随卫星天项角(≤75°)的变化可以很好地用Secant律来表示。该算式的精度优于其他模型;不同气候地区要采用根据当地气象资料建立起的订正算式 相似文献
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综合应用137Cs技术、RS技术和GIS技术,进行云南小江流域土壤侵蚀的评估和预测研究,探索中国西部山区观测资料缺乏、USLE(Universal Soil Loss Equation)方程不适宜区域土壤侵蚀评估与预测方法。通过137Cs技术,采用非农耕地与农耕地土壤侵蚀模型确定区内林地、灌丛、草地、坡耕地和裸地的年均侵蚀模数分别为356—1531 t/(km2·a),330—1709 t/(km2·a),886—3885 t/(km2·a),5197—12454 t/(km2·a)和15000 t/(km2·a)以上。解译小江流域1987年(Landsat TM)、1995年(Landsat TM)和2005年(Landsat ETM)遥感影像,获得流域不同时期土地利用图,将其与1∶50000 DEM模型进行叠置分析,建立小江流域土地利用的空间分布图,结合利用137Cs确定的土壤侵蚀速率数据,进行土壤侵蚀分区与制图,分析土壤侵蚀的时空变化。结果表明:1987年—2005年流域轻度以上侵蚀面积占总面积的66.0%—67.3%,变化不大,但侵蚀强度明显加剧,1987年—1995年间尤为明显;中度侵蚀、强度侵蚀、极强度侵蚀区面积分别增加30%、23%和26%;小江流域1987年、1995年和2005年土壤侵蚀量分别为7.51×106t/a,8.19×106t/a和8.18×106t/a。进而选用1995年和2005年的土壤侵蚀数据构建Markov-CA(马尔可夫—元胞自动机)预测模型,获得2015年流域土壤侵蚀分区图,并预测2015年土壤侵蚀量为8.17×106t,与2005年侵蚀量接近。研究结果真实地反映了小江流域土壤侵蚀的变化过程与主要驱动因子,研究方法适合中国西部山区土壤侵蚀评估与预测。 相似文献
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为降低云对MODIS逐日积雪覆盖产品MOD10A1和MYD10A1在新疆积雪实时监测与研究中的影响,引入交互式多传感器雪冰制图系统(interactive multi-sensor snow ice mapping system,IMS)等多源遥感数据和地面实测资料,综合时间滤波法、空间滤波法及多传感器融合法等不同的去云技术,建立基于多源数据的去云方法,生成新疆地区2002—2016年近15 a间逐日无云积雪覆盖产品数据,并利用实测资料对生成的产品数据进行精度评价及结果验证。结果表明,去云后积雪覆盖产品在新疆积雪覆盖的总体监测精度为90.61%,接近于去云前MODIS晴空积雪覆盖产品在新疆的总体监测精度(93.3%)。 相似文献
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T639-GSI全球系统同化AMSU-A资料的过程中,目前使用的月平均积雪产品并不能反映中高纬度大陆上快速地降雪/融雪过程,而FY-3C日积雪产品在时间精度上要高于GSI月平均积雪覆盖数据。由于同化系统对AMSU-A较低通道辐射率资料的质量控制需要依据更准确的地表积雪信息,所以本文结合冬春季节的FY-3C日积雪产品和NCEP再分析资料,研究了北半球中高纬度地区不同积雪覆盖率初值对分析场不同高度层温度场的影响,以及在同化过程中对预报结果的影响。结果表明,在对AMSU-A辐射率资料的质量控制中,月平均积雪数据和日积雪产品对温度场影响较大的区域与两者积雪覆盖差异区域有明显的对应;冬春季节,使用FY-3C日积雪产品代替GSI月平均积雪数据作为背景场中积雪下垫面数据,对进入同化系统的AMSU-A辐射率资料质量控制时,120 h之内1000—600 h Pa的中低层温度场的预报效果得到改善。 相似文献
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田晓飞 《测绘与空间地理信息》2023,(4):152-154
基于1977—2017年的Landsat卫星数据,研究区域积雪季节变化特征以及积雪变化与气候特征之间的响应机制。对Lantsat数据采用面向对象法、雪盖指数法提取波密县流域的积雪像元,研究结果表明,近40年来波密县流域积雪面积在年际尺度上整体面积急剧下降,40年间积雪覆盖率由67%下降至18%,尤其是2007—2017这10年,波密县流域的积雪面积呈现明显下降的趋势。全球气候变暖可能是波密县流域积雪面积不断变小的主要原因。 相似文献
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采用基于质能平衡的积雪过程模型—雪热力模型(Snow Thermal Model, SNTHERM.89)来描述和模拟2008年中国甘肃省黑河实验冰沟流域的积雪过程与积雪特性参数,并将模型模拟的雪水当量与高级微波扫描辐射计(AMSR-E)的雪水当量产品进行了对比。模型验证结果表明,SNTHERM模型能准确模拟黑河冰沟流域的积雪变化过程和积雪特性,对积雪的演变特征作出合理的描述,表明SNTHERM在中国黑河冰沟流域有较好的适用性。对SNTHERM模型进行不同驱动气象参数和初始输入参数的敏感性分析的结果表明,积雪特性参数对辐射通量最敏感;各积雪特性参数对各自的初始输入比较敏感,密度则对初始输入的雪深、密度和颗粒大小都比较敏感,表明在需要准确模拟密度的情况下以及进行雪水当量同化工作时,初始输入的雪层深度、密度和颗粒都必须比较准确。 相似文献
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This work provides an overview of various methods for estimating snow cover and properties in high mountains using remote sensing techniques involving microwaves. Satellite-based remote sensing with its characteristics such as synoptic view, repetitive coverage and uniformity over large areas has great potential for identifying the temporal snow cover. Many sensors have been used in the past with various algorithms and accuracies for this purpose. These methods have been improving with the use of Synthetic Aperture Radar sensors, working in different microwave frequencies, polarisation and acquisition modes. The limitations, advantages and drawbacks are illustrated while error sources and strategies on how to ease their impacts are also reviewed. An extensive list of references, with an emphasis on studies since 1990s, allows the reader to delve into specific topics. 相似文献
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利用MTSAT-2静止气象卫星数据开展了中国区域的雪盖监测研究,结合MODIS雪盖产品及站点雪深观测数据对判识结果进行对比分析和验证。首先,根据MTSAT-2静止气象卫星数据特点,进行角度效应校正及多时相数据合成,以减少云对图像的影响;其次,根据多个雪盖判识因子建立中国区域雪盖判识算法;最后,对比分析2011年1月份MTSAT-2和MODIS雪盖判识结果,并使用站点观测数据进行精度验证。研究表明:(1)MTSAT-2雪盖判识受云影响比例约30%,MODIS雪盖产品受云影响比例约60%,MTSAT-2去云效果明显。(2)无云情况下,MTSAT-2雪盖判识和MODIS雪盖产品判识精度均高于92%;有云覆盖时,MTSAT-2判识精度约65%,优于MODIS雪盖产品35%的判识精度。(3)MTSAT-2静止气象卫星在保持高积雪判识精度的前提下,可以更有效减少云对雪盖判识影响,实时获取更多地表真实信息。该研究对中国区域雪盖信息准确监测、气候变化研究以及防灾减灾等具有重要意义。 相似文献
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利用NOAA AVHRR数据研究北半球雪盖气候学特征 总被引:2,自引:0,他引:2
利用NOAA卫星图像,研究了北半球、欧亚、北美和青藏高原雪盖气候学特征及其变化趋势.指出北半球、欧亚和北美雪盖气候变化趋势基本一致,年均雪盖面积在1987年前后明显下降; 而青藏高原雪盖面积在1984年后明显下降,说明青藏高原雪盖的年际变化与北半球及欧亚、北美不完全一致. 相似文献
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利用被动微波遥感反演积雪深度一直是积雪遥感领域中的研究热点。在现有的积雪深度反演算法中,NASA算法因其简洁、易于扩展的特点,成为应用最为广泛的算法。但NASA算法存在着一定不足:首先,由于NASA算法基于线性拟合得出,在应用到其他研究区域时需要对反演公式进行重新拟合,适用范围受到一定限制;其次,由于算法中引入的19GHz与37GHz的亮温差在雪深达到一定范围时会达到饱和,因此算法会低估积雪深度。本文针对现有反演算法的不足之处,结合蚁群智能算法的特点,发展了基于蚁群算法的积雪深度反演算法;此外,针对NASA算法中存在的雪深低估问题,引入了AMSR-E10.7GHz亮温数据,对算法进行了改进。利用MEMLS模型的模拟数据与AMSR-E辐射亮温数据对算法进行实验,并采用实测数据与AMSR-E雪水当量产品对算法的反演精度进行评价。结果表明,两种积雪深度反演算法均是可行的,反演精度与现有产品相比有较为明显的改进。 相似文献
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This paper proposes an applicable approach for snow information abstraction in northern Xinjiang Basin using MODIS data. Linear
spectral mixture analysis (LSMA) was used to calculate snow cover fractions (SF) within a pixel, which was used to establish
a regression function with NDSI. In addition, 80 snow depths samples were collected in the study region. The correlation between
image spectra reflectance and snow depth as well as the comparison between measured snow spectra and image spectra was analyzed.
An algorithm was developed for snow depth inversion on the basis of the correlation between snow depth and snow spectra in
the region. The results indicated that the model of SF had a high accuracy with the mean absolute error 0.06 tested by 26
true measured values and the validation for snow depth model using another dataset with 50 sampling sites showed an RMSE of
1.63. Our study showed that MODIS data provide an alternative method for snow information abstraction through development
of algorithms suitable for local application.
Supported by the National Natural Science Foundation of China (No.70361001). 相似文献
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Snow cover mapping is important for snow and glacier-related research. The spatial and temporal distribution of snow cover area is a fundamental input to the atmospheric models, snowmelt runoff models and climate models, as well as other applications. Daily snow cover maps from Moderate Resolution Imaging Spectroradiometer (MODIS) Terra satellite were retrieved for the period between 2004 and 2007, and pixels in these images were classified as cloud, snow or snow-free. These images have then been compared with ground snow depth (SD) measurements from the four observatories located at different parts of Himalayas. Comparison of snow maps with in situ data showed good agreement with overall accuracies in between 78.15 and 95.60%. When snow cover was less, MODIS data were found to be less accurate in mapping snow cover region. As the SD increases, the accuracy of MODIS snow cover maps also increases. 相似文献
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In high-altitude areas, snow cover plays a significant role in mountainous hydrology. Satluj, which is a snow-fed river, is a part of the Indus River system in the western Himalayas. Snow cover area (SCA) variability in this river basin affects the spatio-temporal flow availability and avalanche events. Keeping this in mind, the present study focuses on SCA variability and its relationship with various topographical features such as elevation, slope and aspect. The study has been carried out in the upper part of the Satluj River Basin on the basis of MODIS Terra (MOD10A2) data from 2001 to 2014. It has been noticed that the average annual SCA in this part of the Satluj River Basin varies from 44 to 56% with an average of about 48% of the total basin area of 16, 650 km2. Further, snow accumulation and depletion curves have been suggested for assessing the SCA in the study area. 相似文献
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This study maps the geographic extent of intermittent and seasonal snow cover in the western United States using thresholds of 2000–2010 average snow persistence derived from moderate resolution imaging spectroradiometer snow cover area data from 1 January to 3 July. Results show seasonal snow covers 13% of the region, and intermittent snow covers 25%. The lower elevation boundaries of intermittent and seasonal snow zones increase from north-west to south-east. Intermittent snow is primarily found where average winter land surface temperatures are above freezing, whereas seasonal snow is primarily where winter temperatures are below freezing. However, temperatures at the boundary between intermittent and seasonal snow exhibit high regional variability, with average winter seasonal snow zone temperatures above freezing in west coast mountain ranges. Snow cover extent at peak accumulation is most variable at the upper elevations of the intermittent snow zone, highlighting the sensitivity of this snow zone boundary to climate conditions. 相似文献