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1.
根据2004年的MODIS数据和森林火灾地面调查数据, 以福建省为例, 来探讨典型南方丘陵山区森林火灾发生后火灾面积大小评估的技术方法。在对火区250 m分辨率MODIS数据特征分析的基础上, 通过MODIS近红外通道反射率和归一化植被指数在火灾发生前后的散点图, 结合火区的假彩色合成影像, 利用ENVI软件的ROI处理功能建立火灾面积评估技术方法。对35起森林火灾样本进行评估, 过火面积总体估算误差为15 hm2, 结果表明, 在南方丘陵山区, 应用MODIS数据开展森林火灾面积评估, 能较好地满足业务需求。 相似文献
2.
基于遥感技术(RS)和地理信息系统(GIS),利用由基于DEM演算的地面最高温度、最小相对湿度和最大风速等格点化气象要素,FY2静止气象卫星逐日降水反演产品和AVHRR积雪监测产品计算网格森林火险天气等级,结合由植被类型、NDVI、地形要素和公路、人口聚居地等要素评估的森林火险风险等级,综合计算得到网格化的西藏森林火险等级。该项业务程序基于MeteoInfo组件建立,能够实现全自动化业务运行。对于森林火灾事件,通过与基于气象站的森林火险天气等级相比,该方法的准确性更高,能为西藏林区森林防火工作提供有效参考。 相似文献
3.
为了探索基于多源卫星产品组建长时间序列NDVI并开展生态监测与灾害评估的可能性,利用相关系数、均方根误差、标准差和平均偏差等方法,结合泰勒图,对呼伦贝尔地区2012—2021年基于Terra和NPP卫星逐16 d的NDVI产品进行比较。结果表明:NPP/NDVI的多年均值略高于Terra/NDVI,两者在草原植被类型下的一致性最优,其次为耕地,森林植被的一致性较差。在呼伦贝尔非植被生长季,Terra/NDVI与NPP/NDVI的偏差主要集中在森林,且以Terra/NDVI偏高为主。在植被生长季初期2种NDVI产品的偏差呈现零散、随机分布,中期的偏差相对较小,生长季后期则以Terra/NDVI小于NPP/NDVI的负偏差为主。虽然2种卫星产品的总体偏差不大,但在开展NDVI的距平分析或计算VCI等指数时,较小的偏差会被放大。呼伦贝尔草地在考虑两种NDVI产品偏差纠正的前提下基本可替代使用,而耕地、林地植被的协同应用仍需谨慎。 相似文献
4.
Retrospective satellite image data were evaluated for their ability to demonstrate the influence of center-pivot irrigation development in western Nebraska on spectral change and climate-related factors for the region. Periodic images of an albedo index and a normalized difference vegetation index (NDVI) were generated from calibrated Landsat multispectral scanner (MSS) data and used to monitor spectral changes associated with irrigation development from 1972 through 1986. The albedo index was not useful for monitoring irrigation development. For the NDVI, it was found that proportions of counties in irrigated agriculture, as discriminated by a threshold, were more highly correlated with reported ground estimates of irrigated agriculture than were county mean greenness values. A similar result was achieved when using coarse resolution Advanced Very High Resolution Radiometer (AVHRR) image data for estimating irrigated agriculture.The NDVI images were used to evaluate a procedure for making areal estimates of actual evapotranspiration (ET) volumes. Estimates of ET volumes for test counties, using reported ground acreages and corresponding standard crop coefficients, were correlated with the estimates of ET volume using crop coefficients scaled to NDVI values and pixel counts of crop areas. These county estimates were made under the assumption that soil water availability was unlimited. For nonirrigated vegetation, this may result in over-estimation of ET volumes. Ground information regarding crop types and acreages are required to derive the NDVI scaling factor. Potential ET, estimated with the Jensen-Haise model, is common to both methods. These results, achieved with both MSS and AVHRR data, show promise for providing climatologically important land surface information for regional and global climate models.TGS Technology, Inc. Work performed under U.S. Geological Survey contract 14-08-0001-22521; 相似文献
5.
V. Krishna Prasad K. V. S. Badarinath Anuradha Eaturu 《Theoretical and Applied Climatology》2007,89(1-2):95-107
Summary Leaf phenology describes the seasonal cycle of leaf functioning and is essential for understanding the interactions between
the biosphere, the climate and the atmosphere. In this study, we characterized the spatial patterns in phenological variations
in eight contrasting forest types in an Indian region using coarse resolution NOAA AVHRR satellite data. The onset, offset
and growing season length for different forest types has been estimated using normalized difference vegetation index (NDVI).
Further, the relationship between NDVI and climatic parameters has been assessed to determine which climatic variable (temperature
or precipitation) best explain variation in NDVI. In addition, we also assessed how quickly and over what time periods does
NDVI respond to different precipitation events. Our results suggested strong spatial variability in NDVI metrics for different
forest types. Among the eight forest types, tropical dry deciduous forests showed lowest values for summed NDVI (SNDVI), averaged
NDVI (ANDVI) and integrated NDVI (I-NDVI), while the tropical wet evergreen forests of Arunachal Pradesh had highest values.
Within the different evergreen forest types, SNDVI, ANDVI and INDVI were highest for tropical wet evergreen forests, followed
by tropical evergreen forests, tropical semi-evergreen forests and were least for tropical dry evergreen forests. Differences
in the amplitude of NDVI were quite distinct for evergreen forests compared to deciduous ones and mixed deciduous forests.
Although, all the evergreen forests studied had a similar growing season length of 270 days, the onset and offset dates were
quite different. Response of vegetative greenness to climatic variability appeared to vary with vegetation characteristics
and forest types. Linear correlations between mean monthly NDVI and temperature were found to yield negative relationships
in contrast to precipitation, which showed a significant positive response to vegetation greenness. The correlations improved
much for different forest types when the log of cumulative rainfall was correlated against mean monthly NDVI. Of the eight
forest types, the NDVI for six forest types was positively correlated with the logarithm of cumulative rainfall that was summed
for 3–4 months. Overall, this study identifies precipitation as a major control for vegetation greenness in tropical forests,
more so than temperature. 相似文献
6.
森林火点的识别是利用气象卫星资料监测森林火灾的基础。传统的目视解译火点识别法难以实现计算机的自动识别,神经网络技术为解决这一问题提供了新的工具。作者探讨了应用神经网络实现气象卫星影像森林火点自动识别的技术方法,并在湖北省地理范围内进行了试验。试验结果显示,经过训练的神经网络能够记忆火点的特征,具备将森林火点从气象卫星影像中识别出来的能力。与目视解译法相比,神经网络方法的精度接近目视解译法,最重要的是实现了森林火点的自动识别。 相似文献
7.
内蒙古植被NDVI变化特征分析 总被引:2,自引:0,他引:2
对植被状况和植被覆盖的研究可以反映植被受环境条件影响产生的时空变化。文章根据GIMMS-NDVI数据集1982—2006年影像数据,分析内蒙古农田、森林、草原三种植被类型NDVI年内、年际的变化趋势以及植被覆盖变化特征的空间差异。各植被类型变化曲线都呈现4—7月NDVI激增,8—10月NDVI猛降,冬季农田、草原植被覆盖接近裸土的特点。农田夏季NDVI平均值的历年线性变化趋势通过显著性检验,森林夏季NDVI平均值呈现下降的趋势,草原夏季NDVI平均值呈现上升的趋势,但都不显著。 相似文献
8.
Determining Effects of Area Burned and Fire Severity on Carbon Cycling and Emissions in Siberia 总被引:14,自引:0,他引:14
Susan G. Conard Anatoly I. Sukhinin Brian J. Stocks Donald R. Cahoon Eduard P. Davidenko Galina A. Ivanova 《Climatic change》2002,55(1-2):197-211
The Russian boreal forest contains about 25% of the global terrestrial biomass, and even a higher percentage of the carbon stored in litter and soils. Fire burns large areas annually, much of it in low-severity surface fires – but data on fire area and impacts or extent of varying fire severity are poor. Changes in land use, cover, and disturbance patterns such as those predicted by global climate change models, have the potential to greatly alter current fire regimes in boreal forests and to significantly impact global carbon budgets. The extent and global importance of fires in the boreal zone have often been greatly underestimated. For the 1998 fire season we estimate from remote sensing data that about 13.3 million ha burned in Siberia. This is about 5 times higher than estimates from the Russian Aerial Forest Protection Service (Avialesookhrana) for the same period. We estimate that fires in the Russian boreal forest in 1998 constituted some 14–20% of average annual global carbon emissions from forest fires. Average annual emissions from boreal zone forests may be equivalent to 23–39% of regional fossil fuel emissions in Canada and Russia, respectively. But the lack of accurate data and models introduces large potential errors into these estimates. Improved monitoring and understanding of the landscape extent and severity of fires and effects of fire on carbon storage, air chemistry, vegetation dynamics and structure, and forest health and productivity are essential to provide inputs into global and regional models of carbon cycling and atmospheric chemistry. 相似文献
9.
基于GIS空间分析和数学统计方法,利用TERRA、AQUA和NPP-VIIRS卫星数据反演了西藏日土县植被归一化指数(Normalized Difference Vegetation Index,NDVI),并对不同卫星传感器反演结果的一致性进行了检验评估。结果表明:NPP-VIIRS卫星反演的NDVI值略大于TERRA和AQUA的反演值,其估算结果与MODIS卫星估算值存在较好的相关性。NPP-VIIRS卫星可以用于西藏高原植被长势监测工作,为西藏生态文明高地建设提供更加丰富的遥感数据支撑。 相似文献
10.
Development of the IAP Dynamic Global Vegetation Model 总被引:1,自引:0,他引:1
ABSTRACT The lAP Dynamic Global Vegetation Model (IAP-DGVM) has been developed to simulate the distribution and structure of global vegetation within the framework of Earth System Models. It incorporates our group's recent developments of major model components such as the shrub sub-model, establishment and competition parameterization schemes, and a process-based fire parameterization of intermediate complexity. The model has 12 plant functional types, including seven tree, two shrub, and three grass types, plus bare soil. Different PFTs are allowed to coexist within a grid cell, and their state variables are updated by various governing equations describing vegetation processes from fine-scale biogeophysics and biogeochemistry, to individual and population dynamics, to large-scale biogeography. Environmental disturbance due to fire not only affects regional vegetation competition, but also influences atmospheric chemistry and aerosol emissions. Simulations under observed atmospheric conditions showed that the model can correctly reproduce the global distribution of trees, shrubs, grasses, and bare soil. The simulated global dominant vegetation types reproduce the transition from forest to grassland (savanna) in the tropical region, and from forest to shrubland in the boreal region, but overestimate the region of temperate forest. 相似文献