基于时序NDVI的石羊河流域植被时空变化规律研究

基于2000-2017年石羊河流域NDVI时间系列数据,利用Landsat系列卫星的TM、ETM、OLI数据获取了研究区的NDVI;并根据NDVI时序变化特征,利用趋势分析法,结合气象数据,研究了近18a来石羊河流域NDVI时空演变的规律。研究结果表明:①2000-2017年石羊河流域时序NDVI总体呈上升趋势,说明植被覆盖程度具有明显增长的趋势;②不同区域NDVI变化差异明显,总体可划分为显著增加、增加、稳定、减少、显著减少5类;③年际NDVI平均值、最大值与气温、降水相关性分析表明,二者与气温相关性在2000-2010年为负相关、在2011-2017年为正相关,二者与降水量总体呈正相关,相关系数分别为0.09、0.29,降水量的增大有利于促进石羊河流域植物的生长。     

澜沧江流域2000-2017年植被NDVI时空特征及其对气候因子的响应

基于MODIS-NDVI数据分析澜沧江流域生长季植被NDVI时空特征和变化趋势,结合地形数据、气象站点数据和植被类型数据,利用趋势分析和相关性分析法研究植被NDVI变化对气候因子的响应。结果表明:1)2000-2017年澜沧江流域生长季植被NDVI均值为0.592,整体呈现出由西北向东南波动增加趋势,增长速率为0.09%/10年;2) 2000-2017年澜沧江流域气温呈上升趋势,降水呈下降趋势,植被NDVII总体与平均气温的相关性高于累积降水量;3)澜沧江流域生长季植被NDVI驱动因子分析表明,气候驱动中以气温降水联合驱动为主,流域植被NDVI变化整体为非气候驱动。     

近30年来渭河流域植被与气候变化互影响模式的探寻分析

基于1982-2006年间的GIMMS NDVI和2001-2013年的MODIS NDVI数据对渭河流域30年来植被NDVI的年际变化和空间分布特征进行了分析,并结合研究区内的气象数据探讨了植被NDVI与气候因子的相互影响关系。研究显示,近32年间渭河流域植被NDVI整体呈上升趋势,且空间差异显著,主要表现为流域西北地区的黄土丘陵沟壑区及北部的黄土高原区NDVI较低,植被覆盖较差;流域南部的秦岭山区、关中平原区等地植被生长状况较好。流域气温和降水呈现缓慢增长趋势。植被NDVI与年均气温整体上表现为负相关,与年降水量间呈正相关。总体上,降水是渭河流域植被生长的主要影响因子。     

长江上游安宁河流域植被生长变化对气候条件的响应

为探讨安宁河流域植被演变趋势及其与气候的相互作用,基于2001—2008年MODIS图像、降水量和气温数据,采用回归分析和相关分析等方法计算了安宁河流域降水、气温和归一化差值植被指数(normalized difference vegetation index,NDVI)在时间和空间上的变化情况,并对安宁河流域植被生长变化对气候条件的响应机制进行了探讨。结果表明:NDVI变化和气温、降水呈正相关;降水量和气温等气候因子的变动会直接反映在植被长势上,其中降水对安宁河流域植被生长的影响更为显著;植被长势与气温和降水存在一定的时间滞后性。     

基于MODIS-NDVI的天津市蓟州区植被特征时空变化分析

基于MODIS-NDVI数据和气象数据,研究了天津市蓟州区植被NDVI近16年的时空变化特征以及16年间气温、降水变化规律.研究结果表明,蓟州区2000-2015年年平均NDVI趋势为先降后升,最低值出现在2004年.月际NDVI均值与月平均降水量的相关性高于最大降水量的相关性,说明最低温度比最高温对植被的影响更大,月平均降水量比最大降水量对植被的影响更大.除去人类活动的影响,蓟州区县植被指数的变化主要归因于降水减少和温度增加,对于指导当地生产实践具有实际意义.     

羌塘国家自然保护区近十年归一化植被指数的研究

本文利用时序的NDVI数据及气象资料(气温、降水),对羌塘国家自然保护区东、中、西部各县近10年NDVI、气温、降水变化及其相关性进行分析。研究表明,近10年来,保护区东部NDVI呈显著上升趋势,植被覆盖增加,中部和西部呈下降趋势,植被覆盖减少,东部年均NDVI与气温呈显著正相关、与降水呈显著负相关,中部反之;西部年均NDVI与气温、降水均呈显著负相关。     

秦岭北麓土地利用变化对植被指数影响研究

以土地利用、MODIS NDVI、年平均气温、年降水量数据为基础,采用线性趋势、F检验等方法,分析了秦岭北麓土地利用和NDVI时空变化特征,及土地利用变化对植被指数变化影响。研究表明：(1)秦岭北麓2000—2015年土地利用类型以林地和耕地为主,平均分别占总面积的52.70%和38.37%。土地利用变化特征表现为耕地减少比例最高、建设用地增加比例最高和增速最快。(2)以2007年为界线,NDVI变化反映出秦岭北麓2000—2007年植被生态较好,之后（2008—2018年）趋于变差。南部山地区域NDVI显著增加,北部平原区域NDVI显著降低。(3)2000—2015年秦岭北麓气温升高、降水增多,为NDVI增加提供了有利的自然条件。但秦岭北麓平原区域NDVI呈下降趋势,其主要原因是人类活动引起的耕地、林地、草地和未利用地向建设用地转变,导致NDVI快速下降。研究证明限制人类活动对保护秦岭北麓植被生态具有重要的实践意义。     

河西地区NDVI变化及其对气温和降水的响应

针对不同地区植被变化对气温和降水的响应不一致的现象,该研究基于MODIS-NDVI遥感影像及同期33个气象站点数据,采用斜率分析和相关分析等方法,探究了河西地区2000-2017年生长季植被覆盖的年际和年内变化及其与气候因子的关系.结果表明:河西地区生长季NDVI的总体水平偏低,空间上由东南向西北逐步递减;近18年,河西地区NDVI的趋势变化为整体增加,增加速率为0.022/(10 a).年尺度上,河西地区NDVI变化与气温相关性较小,主要受降水影响,86.80％的区域与降水呈正相关.月尺度上,植被覆盖随温度升高而逐渐增加,20℃时趋于最大;月降水量在0～60 mm之间时,NDVI随降水量增大而快速增加;超过60 mm后,则稳定在0.16左右.河西地区植被对降水的响应存在2个月滞后性,而与气温则无明显时滞性.     

25年来秦岭NDVI指数的气候响应

利用1982—2006年的植被指数和研究区域内4个气象站的气温、降水数据,研究陕西秦岭地区植被指数、气温、降水的多年变化趋势,分析植被指数与气温和降水的相关关系。利用植被类型数据分析不同植被种类的NDVI与不同气候因子的相关程度。结果表明,1982—2006年,研究区域年均气温有明显的上升,升幅达2.1℃,而年总降水量每10年下降约72 mm,秦岭地区NDVI略有上升。整体而言,植被指数的变化与气温之间的相关性在中部最大,向东西两侧递减;与降水之间的相关性在中部最小,向东西两侧递增。气温对果树园、经济林的影响最大,降水对阔叶林的影响最大。气温是影响该地区植被指数变化的主要因素。     

伊犁河谷天然植被覆盖度的变化特征分析

利用2000-2015年植被生长季(4~10月)MODIS/NDVI产品反演生成同时相的植被覆盖度数据,运用趋势性分析方法和皮尔逊相关系数法,进行了不同类型自然植被覆盖度时空变化特征及其与降水量、平均气温的驱动因素分析。结果表明从多年平均状态看,针叶林的植被覆盖度高于其他天然植被,灌丛类的最低,荒漠和灌丛类的植被覆盖度总体呈递增趋势;从年际尺度上看,草原和灌丛类植被对气温和降水量的响应规律大致呈反方向;不同类植被在春季(4月)对气温和降水量反映的差异性最大,与春季为新疆融雪高峰期有一定关系。     

应用卫星与气象数据及其关系研究黄河流域的荒漠化现状

本文应用20年（1981—2000年）的卫星数据反演归一化差值植被指数（NDVI）,同时获取地面格网的温度与降雨数据,并分析这些数据之间的关系。基于地面的温度和降雨格网数据将研究区划分为8个气候区域,再利用NDVI数据把降雨量最少的3个气候区——区1,2,3各划分为10个等级。此外,分析这3个气候区在1983—1998年15年间的NDVI变化状况,结果显示出研究区荒漠化状况的加剧。     

Study of normalized difference vegetation index variation and its correlation with climate factors in the three-river-source region

Using NOAA/AVHRR 10-day composite NDVI data and 10-day meteorological data, including air temperature, precipitation, vapor pressure, wind velocity and sunshine duration, at 19 weather stations in the three-river-source region in the Qinghai–Tibetan Plateau in China from 1982 to 2000, the variations of NDVI and climate factors were analyzed for the purpose of studying the correlation between climate change and vegetation growth as represented by NDVI in this region. Results showed that the NDVI values in this region gradually grew from the west to the east, and the distribution was consistent with that of moisture status. The growing season came earlier due to climate warming, yet because of the reduction of precipitation, maximal NDVI during 1982–2000 did not show a significant change. NDVI related positively to air temperature, vapor pressure and precipitation, but negatively related to sunshine duration and wind velocity. Furthermore, the response of NDVI to climate change showed time lags for different climate factors. Water condition and temperature were found to be the most important factors effecting the variation of NDVI during the growing season in both the semi-arid and the semi-humid areas. In addition, NDVI had a better correlation with vapor pressure than with precipitation. The ratio of precipitation to evapotranspiration, representing water gain and loss, can be regarded as a comprehensive index to analyze NDVI and climate change, especially in areas where the water condition plays a dominant role.     

Spatial-temporal changes of NDVI and their relations with precipitation and temperature in Yangtze River basin from 1981 to 2001

Multitemporal NOAA/AVHRR NDVI images and monthly temperature and precipitation data were obtained across Yangtze River basin covering the period 1981–2001. The spatial and temporal patterns of NDVI are the same, while spatial analysis shows that the NDVI is influenced by the vegetation types growing in the study regions, and NDVI presents an increasing trend during the study period in the whole basin. The climate indicators play an important role in the changes of vegetation cover in the river basin. In the two Indicators, temperature has a significant effect on the NDVI values than precipitation in the whole basin. However, in the 11 subbasins, the different rules are shown in different subbasins.     

2000-2012年鄂尔多斯高原植被动态及干旱响应

针对鄂尔多斯高原植被覆盖变化受干旱胁迫的状况,该文结合降水和气温的协同变化,以2000-2012年生长季的MODIS-NDVI数据和同期降水、温度和帕尔默干旱指数为依据,采用线性趋势分析、标准偏差分析和相关性分析等方法,对鄂尔多斯高原植被与气候变化的相关关系和干旱异常变化对植被动态的影响进行了研究.结果表明:鄂尔多斯高原生长季及季节(春季、夏季和秋季)植被归一化植被指数主要受降水的控制和干旱的制约,秋季归一化植被指数更多地受到夏季干旱的影响.与气象因子的空间相关分析表明,春季温度上升有利于研究区北部归一化植被指数像元的增加.在荒漠草原和沙漠地区,夏季干旱与归一化植被指数的相关关系最强.秋季降水对典型草原归一化植被指数的提升显著.     

MODIS NDVI和AVHRR NDVI 对草原植被变化监测差异

以草地作为研究载体,对比分析草原植被AVHRR NDVI和MODIS NDVI两种NDVI序列的年内、年际变化特征,讨论两种NDVI序列对降水量、平均气温和水汽压3种气候因子的响应差异,为合理选择NDVI序列对植被进行监测研究提供参考。结果表明：(1)两种NDVI序列所反映的草原植被年内变化趋势相似,但MODIS NDVI对各类草原的区分度优于AVHRR NDVI;(2)两种NDVI序列所反映的2000年—2003年草原植被年际变化差异明显。较之于MODIS NDVI,AVHRR NDVI变化趋势分类图表现出更强的植被改善趋势,植被改善面积在AVHRR NDVI变化趋势分类图中占94.25%,在MODIS NDVI中为83.33%;两种NDVI变化趋势分类图反映的植被变化趋势吻合度为52.88%。(3)两种NDVI序列与水汽压、降水量相关性差异显著。MODIS NDVI与各站点平均气温的相关系数均大于GIMMS NDVI;而MODIS NDVI与水汽压的相关系数83%(10个站点)小于GIMMS NDVI,与降水量的相关系数67%(8个站点)小于GIMMS NDVI。     

中国夏季气候对植被覆盖的影响:1982～2001(英文)

In this paper, we apply lagged correlation analysis to study the effects of vegetation cover on the summer climate in different zones of China, using NOAA/AVHRR normalized difference vegetation index (NDVI) data during the time period from 1982 to 2001 and climate data of 365 meteorological stations across China (precipitation from 1982 to 2001 and temperature from 1982 to 1998). The results show that there are positive correlations between spring NDVI and summer climate (temperature and precipitation) in m...     

High positive correlation between soil temperature and NDVI from 1982 to 2006 in alpine meadow of the Three-River Source Region on the Qinghai-Tibetan Plateau

Using satellite-observed Normalized Difference Vegetation Index (NDVI) data and Rotated Empirical Orthogonal Function (REOF) method, we analyzed the spatio-temporal variation of vegetation during growing seasons from May to September in the Three-River Source Region, alpine meadow in the Qinghai-Tibetan Plateau from 1982 to 2006. We found that NDVI in the centre and east of the region, where the vegetation cover is low, showed a consistent but slight increase before 2003 and remarkable increase in 2004 and 2005. Impact factors analysis indicted that among air temperature, precipitation, humid index, soil surface temperature, and soil temperature at 10 cm and 20 cm depth, annual variation of NDVI was highly positive correlated with the soil surface temperature of the period from March to July. Further analysis revealed that the correlation between the vegetation and temperature was insignificant before 1995, but statistically significant from 1995. The study indicates that temperature is the major controlling factor of vegetation change in the Three-River Source Region, and the currently increase of temperature may increase vegetation coverage and/or density in the area. In addition, ecological restoration project started from 2005 in Three-River Source Region has a certain role in promoting the recovery of vegetation.     

Analysis of China vegetation dynamics using NOAA-AVHRR data from 1982 to 2001

The authors derived the normalized difference vegetation index (NDVI) from the NOAA/AVHRR Land dataset, at a spatial resolution of 8km and 15-day intervals, to investigate the vegetation variations in China during the period from 1982 to 2001. Then, GIS is used to examine the relationship between precipitation and the Normalized Difference Vegetation Index (NDVI) in China, and the value of NDVI is taken as a tool for drought monitoring. The results showed that in the study period, China’s vegetation cover had tended to increase, compared to the early 1980s; mean annual NDVI increased 3.8%. The agricultural regions (Henan, Hebei, Anhui and Shandong) and the west of China are marked by an increase, while the eastern coastal regions are marked by a decrease. The correlation between monthly NDVI and monthly precipitation/temperature in the period 1982 to 2001 is significantly positive (R2=0.80, R2=0.84); indicating the close coupling between climate conditions (precipitation and temperature) and land surface response patterns over China. Examination of NDVI time series reveals two periods: (1) 1982–1989, marked by low values below average NDVI and persistence of drought with a signature large-scale drought during the 1982 and 1989; and (2) 1990–2001, marked by a wetter trend with region-wide high values above average NDVI and a maximum level occurring in 1994 and 1998.