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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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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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基于多尺度统计样本的天山山区MOD10A1分类精度评价 总被引:1,自引:0,他引:1
以2007年5月15号晴空状态下获取的天山地区MOD10A1积雪遥感影像和Landsat-5 TM数据为基础,通过SNOMAP算法提取基于Landsat-5 TM数据的天山山区积雪分类图(30 m×30 m)。将MOD10A1数据与Landsat-5 TM积雪分类图进行对比分析,并分别在50像元×50像元、10像元×10像元和3像元×3像元统计样本尺度上对其进行定量的质量评价。结果表明:随着统计空间尺度的减小,晴空状态下MOD10A1积雪产品的分类精度有降低趋势,上述不同统计尺度上的分类精度分别为0.94、0.87与0.80,说明受空间分辨率的限制,MOD10A1积雪产品的应用存在有效尺度及最优尺度的问题;同时,在上述不同统计尺度上各代表性样方的精度值间的方差呈增大趋势,分别为0.032、0.074与0.135,说明误差增大的同时,MOD10A1数据质量的稳定性在下降。 相似文献
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积雪深度是大量气候、水文、农业及生态模型的重要输入变量。选用欧空局Sentinel-1主动微波数据,利用合成孔径雷达SAR(Synthetic Aperture Radar)差分干涉测量技术的二轨法,根据积雪相位与雪深之间的转换关系,反演新疆天山中段的巴音布鲁克盆地典型区的积雪雪深分布,提出了基于InSAR二轨差分的雪深估计方法,反演得到2016年12月18日的空间分辨率为13.89 m的雪深分布。研究表明:(1)对Sentinel-1数据进行正确的预处理以后,可以应用SAR差分干涉测量技术的二轨法反演区域雪深分布。但由于像对相干性和积雪状态的差异,积雪深度超过10 cm,可以获取较准确的雪深反演结果,R=0.65,反演误差的均方根误差RMSE=4.52 cm,平均相对误差为22.42%,反演雪深结果均比实测结果略偏低;而当雪深小于10 cm时,雪深反演值较实测值存在较大的误差,相对误差均高于34.52%,且反演雪深值均比实测值偏高。(2)雪深反演精度受高程及实际雪深的差异影响显著,另外雪深反演精度也受限于干涉像对相干性。结果表明,对于获取区域积雪雪深,InSAR技术较光学及被动微波遥感具有非常广阔的应用前景。 相似文献
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天山典型林带积雪的多角度遥感识别 总被引:1,自引:1,他引:0
天山中段的山地针叶林带很大程度上影响了该地区整体卫星雪盖的识别精度,多角度卫星遥感技术的发展为林区积雪识别提供了新的途径。本文选取了2000年4月至2001年6月,10个时段研究区内无云覆盖的(Multi-angle Imaging Spectro Radiometer)MISR多角度数据,首先对红光波段不同角度观测结果组成的角度谱图像进行非监督分类,以确定天山林带的分布区域,然后在玛纳斯河中下游与那拉提山东部选取典型像元,分析这些像元红光波段各角度反射率在林区不同积雪覆盖状况下的表现差异。研究发现,若林区存在积雪,0°,±26.1°,±45.6°五个观测角度反射率的平均值大于0.1,在部分降雪月份,后向45.6°观测的反射率大于天顶方向观测的2.5倍。根据这一结论,给出基于MISR数据的研究区不同时段的积雪识别结果。结果表明,MISR红光波段对林区积雪反应敏感,不同角度观测的反射率在林区有雪和无雪时差异较大,故可利用多角度遥感信息进行林区积雪识别。 相似文献
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《武汉大学学报(信息科学版)》2016,(6)
在积雪深度研究中,地面资料插值产生的平滑效应以及遥感空间分辨率不足的问题,在很大程度上影响着积雪深度的估计精度。本文采用中高分辨率成像光谱仪(moderate resolution imaging spectro-radiometer,MODIS)和微波扫描辐射计(advanced microwave scanning radiometer-EOS,AMSR-E)融合后的无云积雪面积产品构建虚拟站点,弥补了气象站点少且不均匀的不足,修正雪深克里金插值产生的平滑效应。同时,提出了基于数据同化算法融合以地面观测资料为基础的克里金空间插值雪深、MODIS积雪面积产品和AMSRE微波反演雪深产品的雪深估计方法。以新疆北疆地区为研究区域进行了算法应用及验证,并选取不同海拔的站点观测资料对融合结果进行验证分析,通过均方根、偏差和相关性系数指标检证了该方法能够有效地提高雪深估计精度。 相似文献
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基于统计回归的积雪覆盖率反演方法适合提取大范围区域的积雪覆盖率,提出了基于归一化积雪指数(NDSI)的非线性积雪覆盖率回归模型,利用阿拉斯加、西伯利亚和内蒙古地区的样本数据进行回归分析,估计模型参数,并利用建立的回归模型提取天山地区和祁连山地区的积雪覆盖率进行了验证。结果显示,基于NDSI的非线性积雪覆盖率回归模型对样本数据的拟合度和利用模型提取的积雪覆盖率精度相对于线性模型均有一定的提高。 相似文献
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《测绘科学》2020,(4)
为天山中段近地表气温研究提供可靠、空间分辨率较高的数据源,该文以气象站气温数据、再分析气温数据以及遥感数据为主要数据源,采用多元回归模型反演了近地表气温并进行精度验证。在此基础上,揭示天山中段近地表气温时空分布特征及其变化趋势。结果表明:①反演精度与实测值相近,且精度较好。②天山中段近地表气温呈四周高,中部低,平原区高,丘陵、山区低的空间分布格局;年际变化呈先升高后降低,年内呈周期性单峰变化的趋势。③2001—2016年天山中段近地表气温以不显著增加为主,占显著降低的区域甚少。研究结果证明用多元回归模型可以提高近地表气温的遥感反演精度,为今后近地表气温研究提供空间分辨率较高的数据及其获取方法。 相似文献
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中国西部积雪SMMR微波遥感的评价与初步应用 总被引:3,自引:0,他引:3
本文根据1978—1987年OSL的可见光影像及地面台站积雪记录,评价了NASA的用微波亮温反演积雪深度的算式。还根据DEM资料,用GIS技术把中国西部分成高山、高原、低山、丘陵及盆地五个单元,分别求得各区域订正算式,并以此计算了中国西部1978—1987年各季的平均雪盖率与雪量及它们的年际变化,为本区积雪影响东亚气候研究,提供了可靠基础资料。 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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基于被动微波遥感的青藏高原雪深反演及其结果评价 总被引:21,自引:0,他引:21
采用修正的张氏雪深反演算法,用SSM/I37GHz和19GHz水平极化亮温值计算了青藏高原及其毗邻地区的积雪深度,对其精度进行了评价,并对误差来源进行了分析,结果显示,此算法能够较好地反映研究区的雪深分布,但局部地区误差较大,总体上雪深被高估,其误差主要来源于冻土,深霜层,植被以及雪层中液态水含量,雪粒的形状和粒径的变化带来的影响,SSM/I数据较低的分辨率和研究区复杂的地形使反演的雪深与观测的雪深缺少可比性,给精度的评价带来影响。 相似文献
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基于MODIS影像的内蒙古草原积雪监测 总被引:2,自引:0,他引:2
光学遥感源MODIS具有高光谱分辨率、高时间分辨率、高空间分辨率、全球范围内免费接收等优势,被广泛应用于洪涝、干旱、森林草原火灾、雪灾等自然灾害的动态监测领域。MODIS数据用于内蒙古草原积雪监测,提取积雪信息在国内尚属空白。本文利用MODIS L1B 500m分辨率数据,经过几何校正、去"双眼皮"预处理,根据归一化差分积雪指数(NDSI)算法和综合阈值判别法对内蒙古自治区2008年1月下旬大范围降雪进行积雪信息提取,制作积雪覆盖图。利用内蒙古生态与农业气象中心发布的雪情遥感监测信息验证积雪覆盖图的准确度。验证结果表明,MODIS数据用于大范围积雪监测非常有效。 相似文献
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In this study, IRS 1C WiFS data have been used for the assessment of two natural resources i.e. forest cover and snow cover. These two resources have a great role to play in various hydrological studies such as floods, soil erosion and water pollution etc. Therefore their assessment is very useful in various hydrological studies and management of these resources. The assessment of snow and forest cover have been made on the basis of multispectral classification and classification of NDVI images. Newly created Uttaranchal state has been taken as the study area. These two resources have been estimated for all the thirteen districts of the state separately. The forest cover area estimated in this study is compared with the available data sets of Forest Survey of India (FSI). The estimated forest is 52%, whereas the forest cover reported by the FSI is 44.5% of the total geographical area of the state. The snow cover is estimated for the period after winter season i.e. maximum snow cover and before next winter season i.e. minimum snow cover. It is found that one quarter of the state is under snow cover covering six districts of the state. As such no estimate of snow cover at regional scale has been made so far therefore comparison of the present assessment could not be made. 相似文献
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V. D. Mishra P. Mathur R. P. Singh 《Journal of the Indian Society of Remote Sensing》2005,33(3):381-393
Snow cover is an important variable for climatic and hydrologic models due to its effect on surface albedo, energy, and mass
balance. Satellite observations successfully provide a global and comprehensive hemispheric-scale record of the short-term,
as well as inter-seasonal variations in snow cover. Passive microwave sensors provide an excellent method to monitor temporal
and spatial variations in large-scale snow cover parameters, overcoming problems of cloud cover. Using microwave remote sensing
data, snow parameters (snow surface temperature, snow water equivalence, scattering index, emissivity, snow depth) have been
retrieved to integrate with the snow cover simulation model developed by SASE for avalanche risk assessment on regional basis.
Multispectral and multitemporal brightness temperature data obtained from the Special Sensor Microwave Imager (SSM/I), flown
onboard the DMSP satellites, for the period November 2000 to April 2001 and from November 2001 to February 2002 have been
analysed. A comparative data set on snow measurements and meteorological observations of a region covering large area of Pir-Panjal
and the Greater Himalayan range, available on near real time basis from SASE field observatories were also used. Model calculations
were carried out to study the effects of atmospheric transmission on the microwave radiation emitted from the snow covered
and snow free ground and atmosphere. The sensitivity of combinations of the SSM/I channels at 19, 37 and 85 GHz, in both horizontal
and vertical polarizations, in respect to snow depth, surface temperature of the snowpack have been carried out. Decision
rule based algorithms are developed to identify snow cover and non-snow area. 相似文献
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Snow effects on alpine vegetation in the Qinghai-Tibetan Plateau 总被引:1,自引:0,他引:1
《International Journal of Digital Earth》2013,6(1):58-75
Understanding the relationships between snow and vegetation is important for interpretation of the responses of alpine ecosystems to climate changes. The Qinghai-Tibetan Plateau is regarded as an ideal area due to its undisturbed features with low population and relatively high snow cover. We used 500 m Moderate Resolution Imaging Spectroradiometer (MODIS) datasets during 2001–2010 to examine the snow–vegetation relationships, specifically, (1) the influence of snow melting date on vegetation green-up date and (2) the effects of snow cover duration on vegetation greenness. The results showed that the alpine vegetation responded strongly to snow phenology (i.e., snow melting date and snow cover duration) over large areas of the Qinghai-Tibetan Plateau. Snow melting date and vegetation green-up date were significantly correlated (p < 0.1) in 39.9% of meadow areas (accounting for 26.2% of vegetated areas) and 36.7% of steppe areas (28.1% of vegetated areas). Vegetation growth was influenced by different seasonal snow cover durations (SCDs) in different regions. Generally, the December–February and March–May SCDs played a significantly role in vegetation growth, both positively and negatively, depending on different water source regions. Snow's positive impact on vegetation was larger than the negative impact. 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
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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