By using NOAA temporal series data during the period 1985一1990 (69 months),this study examines the Vegetation-Cover change with time and space in China. Furthermore, the ana1ysis about correlation . between Vegetation-Cover change and environmental factors is also accomplished by combining simu1taneous average temperature and precipitation .data in each month. The methods employedinclude Sample Transect Ana1ysis, Partia1 Correlation Ana1ysis, and GIS Spatia1 Calcu1ation.From the above ana1ysis, we can draw the following conclusions:1. The vegetation index generally represents the situation of the superficial vegetation cover. Heat and water condition determine the whole spatia1 distribution pattem of vegetation index and build the regional attribute in longitude and latitude. The partia1 fluctuation of the vegetation index is essentia11y affected by landscape and soil conditions. This defines its regiona1 distribution pattem.2. Lying on the same longitude, the vegetation index obviously. corresponds to the seasonal movement law, and span of the movement in time and space is much greater than that along the same latitude. The type and ways of the green wave movement synchronize with the seasonal movement of the continenta1 main controlling air mass and are influenced by it.3.The vegetation index increases and decreases with the warming and cooling of the climate.So it has typically seasona1 change characteristics. Along the same longitude, the higher the latitude is,the greater the scope of seasonal change will be. In summer there is no evident difference of vegetationindex between southem and northem region. But in winter，this difference is quite obvious.4. In a large range, the vegetation index change is driven by water and heat conditions. In eastem moist monsoon zone of China,along. the same longitude,the temperature is the most important influential parameter.The correlation between the vegetation index change and monthly average temperature is obvious.So the heat is key natural limited factor for the growth of the vegetation. Yet,in northem China, along the same latitude, from east to west，it sequentially covers the humid monsoon zone, semi-arid and arid desert zone. The relationship between the vegetation index change and monthly average precipitation is well correlated positively. It proves that in a dry area, water source is the essential limited condition for the growth of the vegetation.

By using NOAA temporal series data during the period 1985一1990 (69 months),this study examines the Vegetation-Cover change with time and space in China. Furthermore, the ana1ysis about correlation . between Vegetation-Cover change and environmental factors is also accomplished by combining simu1taneous average temperature and precipitation .data in each month. The methods employedinclude Sample Transect Ana1ysis, Partia1 Correlation Ana1ysis, and GIS Spatia1 Calcu1ation.From the above ana1ysis, we can draw the following conclusions:1. The vegetation index generally represents the situation of the superficial vegetation cover. Heat and water condition determine the whole spatia1 distribution pattem of vegetation index and build the regional attribute in longitude and latitude. The partia1 fluctuation of the vegetation index is essentia11y affected by landscape and soil conditions. This defines its regiona1 distribution pattem.2. Lying on the same longitude, the vegetation index obviously. corresponds to the seasonal movement law, and span of the movement in time and space is much greater than that along the same latitude. The type and ways of the green wave movement synchronize with the seasonal movement of the continenta1 main controlling air mass and are influenced by it.3.The vegetation index increases and decreases with the warming and cooling of the climate.So it has typically seasona1 change characteristics. Along the same longitude, the higher the latitude is,the greater the scope of seasonal change will be. In summer there is no evident difference of vegetationindex between southem and northem region. But in winter，this difference is quite obvious.4. In a large range, the vegetation index change is driven by water and heat conditions. In eastem moist monsoon zone of China,along. the same longitude,the temperature is the most important influential parameter.The correlation between the vegetation index change and monthly average temperature is obvious.So the heat is key natural limited factor for the growth of the vegetation. Yet,in northem China, along the same latitude, from east to west，it sequentially covers the humid monsoon zone, semi-arid and arid desert zone. The relationship between the vegetation index change and monthly average precipitation is well correlated positively. It proves that in a dry area, water source is the essential limited condition for the growth of the vegetation.

The relationship between climate change and vegetation dynamics in the southwestern karst region of China has been identified by recent studies. Based on previous researches and AVHRR (Advanced Very High Resolution Radiometer) GIMMS (Global Inventory Monitoring and Modeling Studies) NDVI (Normalized Difference Vegetation Index) (1982–2003) and AVHRR GloPEM (Global Production Efficiency Model) NPP (Net Primary Production) (1981–2000) datasets, vegetation dynamics impacted by climate change in the southwestern karst region of China were assessed. The results show that: (1) since the early 1980s, both vegetation cover density and net primary production have insignificant ascending tendencies. However, the inter-annual variation rates of vegetation indexes have apparent spatial differentiations; (2) the correlation coefficients between the inter-annual variations of vegetation indexes and the inter-annual variations of climate factors vary geographically; (3) as indicated by NDVI and NPP, various vegetation types have different responses to climate change, and the annual mean temperature variation has more significant impact on vegetation dynamics than the annual precipitation variation in the study area; (4) distribution laws of correlation coefficients between the inter-annual variations of vegetation indexes and the inter-annual variations of climate factors in different climate conditions are apparent. All these findings will enrich our knowledge of the natural forces which impact the stability of the karst ecosystems and provide scientific basis for the management of the karst ecosystems.

Since implementation of the project of returning farmland to forest and grassland in the Loess Plateau, vegetation cover of the region has been greatly changed. To effectively monitor variation of the vegetation cover, this paper constructs a yearly maximum normalized difference vegetation index (NDVI) sequence covering Loess Plateau from 1982 to 2014 using the per-pixel unary linear regression model (LRM). The work is based on AVHRR GIMMS NDVI datasets from 1982 to 2006 and MODIS NDVI datasets from 2001 to 2014. The constructed NDVI has passed consistency check, and is used to analyze spatial-temporal characteristics of vegetation NDVI in the past 33 years. The following results are obtained. The overall vegetation NDVI of the Loess Plateau in the past 33 years has been increasing. Spatial distribution of the vegetation cover in the regions is significantly different. Vegetation cover has slightly degraded in most southern and western parts of the area under study, and that in the central region is almost unchanged. The vegetation cover shows an improving trend in some areas including the border of Inner Mongolia, Lanzhou, Gansu and Yulin region of Shaanxi. Vegetation covers of different slopes are good. Degrees of changes in areas with different slopes are ranked in a descending order as above 28°, 20°~28°, 14°~20°, 9°~14°, 4°~9°. The vegetation cover in sloping fields of middle part of the Loess Plateau is most improved. Slight improvement of the vegetation cover has been found in areas including eastern Gansu, junction of Gansu and Qinghai provinces, southern Shaanxi, and the cities Linfen, Yuncheng and Sanmenxia of Shanxi, showing positive results in controlling loss of water and soil.

Since implementation of the project of returning farmland to forest and grassland in the Loess Plateau, vegetation cover of the region has been greatly changed. To effectively monitor variation of the vegetation cover, this paper constructs a yearly maximum normalized difference vegetation index (NDVI) sequence covering Loess Plateau from 1982 to 2014 using the per-pixel unary linear regression model (LRM). The work is based on AVHRR GIMMS NDVI datasets from 1982 to 2006 and MODIS NDVI datasets from 2001 to 2014. The constructed NDVI has passed consistency check, and is used to analyze spatial-temporal characteristics of vegetation NDVI in the past 33 years. The following results are obtained. The overall vegetation NDVI of the Loess Plateau in the past 33 years has been increasing. Spatial distribution of the vegetation cover in the regions is significantly different. Vegetation cover has slightly degraded in most southern and western parts of the area under study, and that in the central region is almost unchanged. The vegetation cover shows an improving trend in some areas including the border of Inner Mongolia, Lanzhou, Gansu and Yulin region of Shaanxi. Vegetation covers of different slopes are good. Degrees of changes in areas with different slopes are ranked in a descending order as above 28°, 20°~28°, 14°~20°, 9°~14°, 4°~9°. The vegetation cover in sloping fields of middle part of the Loess Plateau is most improved. Slight improvement of the vegetation cover has been found in areas including eastern Gansu, junction of Gansu and Qinghai provinces, southern Shaanxi, and the cities Linfen, Yuncheng and Sanmenxia of Shanxi, showing positive results in controlling loss of water and soil.

Based on normalized difference vegetation index (NDVI), vegetation type, and meteorological data, this study revealed the seasonal variations of the day- and nighttime warming in growing seasons using unitary linear regression analysis. It examined different effects of asymmetric seasonal warming on vegetation activities in China's temperate zone using the two-order partial correlation analysis method. The results are as follows. (1) The day- and nighttime warming trends from 1982 to 2015 in growing seasons were extremely significant. The day- and nighttime warming rates were featured by asymmetry; daytime warming was slightly faster than nighttime warming in spring and summer. Contrarily, in autumn, nighttime warming was faster than daytime warming. (2) The effects of the day- and nighttime warming on vegetation activity were obviously different; daytime warming had significantly greater and more extensive effects on vegetation than nighttime warming did, and the areas impacted by diurnal warming were broader in spring than in summer and autumn. (3) Different vegetation types responded differently to the seasonal asymmetry in day- and nighttime warming, and the degree of responses showed distinct variations by season.

Based on normalized difference vegetation index (NDVI), vegetation type, and meteorological data, this study revealed the seasonal variations of the day- and nighttime warming in growing seasons using unitary linear regression analysis. It examined different effects of asymmetric seasonal warming on vegetation activities in China's temperate zone using the two-order partial correlation analysis method. The results are as follows. (1) The day- and nighttime warming trends from 1982 to 2015 in growing seasons were extremely significant. The day- and nighttime warming rates were featured by asymmetry; daytime warming was slightly faster than nighttime warming in spring and summer. Contrarily, in autumn, nighttime warming was faster than daytime warming. (2) The effects of the day- and nighttime warming on vegetation activity were obviously different; daytime warming had significantly greater and more extensive effects on vegetation than nighttime warming did, and the areas impacted by diurnal warming were broader in spring than in summer and autumn. (3) Different vegetation types responded differently to the seasonal asymmetry in day- and nighttime warming, and the degree of responses showed distinct variations by season.

Based on GIMMS 3g NDVI, landuse, temperature, precipitation and vegetation type data, the paper fitted the current year vegetation growing season curve and extracted the yearly green-up day of vegetation growing season in northern China in recent 30 years (from 1983 to 2012), analyzed its spatio-temporal changes and also the relationship between temperature and precipitation. In order to meet the actual vegetation growth, we used harmonic analysis of time-series method to reconstruct vegetation NDVI, dynamic threshold and a sixpolynomial fitting method. Some conclusions were as follows. 1) With longer time-series features and better data quality, GIMMS 3g NDVI data with time-series harmonic data analysis was very good to fit and show the actual characteristics of vegetation growing season curve in northern China and can be well used to further study of vegetation growing season in the future. 2) During the study period, green-up day of vegetation growing season mainly distributed from 80 days to 150 days, and the regional averaged value reached 111.6 days.Green-up day of vegetation growing season in regions such as northeast Plain, north China Plain, Hetao Plain, Tianshan, the Altai were earlier. 3) Green-up day of vegetation growing season in northern China showed an advanced tend in general and gradually transitioned from the northwest to the northeast. The significantly advanced regions mainly distributed in the eastern of Inner Mongolia, northeast China Plain, southern Shanxi and the Tianshan Mountains of Xinjiang section area, while the significantly delayed regions were in Qinghai-Tibet Plateau alpine regions. 4) Due to various vegetation types and regional differences and so on,green-up day of vegetation growing season responded to temperature and precipitation distinctly and temperature was the main factor that affecting green-up day of vegetation growing season changes.

Based on GIMMS 3g NDVI, landuse, temperature, precipitation and vegetation type data, the paper fitted the current year vegetation growing season curve and extracted the yearly green-up day of vegetation growing season in northern China in recent 30 years (from 1983 to 2012), analyzed its spatio-temporal changes and also the relationship between temperature and precipitation. In order to meet the actual vegetation growth, we used harmonic analysis of time-series method to reconstruct vegetation NDVI, dynamic threshold and a sixpolynomial fitting method. Some conclusions were as follows. 1) With longer time-series features and better data quality, GIMMS 3g NDVI data with time-series harmonic data analysis was very good to fit and show the actual characteristics of vegetation growing season curve in northern China and can be well used to further study of vegetation growing season in the future. 2) During the study period, green-up day of vegetation growing season mainly distributed from 80 days to 150 days, and the regional averaged value reached 111.6 days.Green-up day of vegetation growing season in regions such as northeast Plain, north China Plain, Hetao Plain, Tianshan, the Altai were earlier. 3) Green-up day of vegetation growing season in northern China showed an advanced tend in general and gradually transitioned from the northwest to the northeast. The significantly advanced regions mainly distributed in the eastern of Inner Mongolia, northeast China Plain, southern Shanxi and the Tianshan Mountains of Xinjiang section area, while the significantly delayed regions were in Qinghai-Tibet Plateau alpine regions. 4) Due to various vegetation types and regional differences and so on,green-up day of vegetation growing season responded to temperature and precipitation distinctly and temperature was the main factor that affecting green-up day of vegetation growing season changes.

Using the Moderate Resolution Imaging Spectroradiometer-normalized difference vegetation index (NDVI) dataset, we investigated the patterns of spatiotemporal variation in vegetation coverage and its associated driving forces in the Qinling-Daba (Qinba) Mountains in 2000-2014. The Sen and Mann-Kendall models and partial correlation analysis were used to analyze the data, followed by calculation of the Hurst index to analyze future trends in vegetation coverage. The results of the study showed that (1) NDVI of the study area exhibited a significant increase in 2000-2014 (linear tendency, 2.8%/10a). During this period, a stable increase was detected before 2010 (linear tendency, 4.32%/10a), followed by a sharp decline after 2010 (linear tendency, -6.59%/10a). (2) Spatially, vegetation cover showed a “high in the middle and a low in the surroundings” pattern. High values of vegetation coverage were mainly found in the Qinba Mountains of Shaanxi Province. (3) The area with improved vegetation coverage was larger than the degraded area, being 81.32% and 18.68%, respectively, during the study period. Piecewise analysis revealed that 71.61% of the total study area showed a decreasing trend in vegetation coverage in 2010-2014. (4) Reverse characteristics of vegetation coverage change were stronger than the same characteristics on the Qinba Mountains. About 46.89% of the entire study area is predicted to decrease in the future, while 34.44% of the total area will follow a continuously increasing trend. (5) The change of vegetation coverage was mainly attributed to the deficit in precipitation. Moreover, vegetation coverage during La Nina years was higher than that during El Nino years. (6) Human activities can induce ambiguous effects on vegetation coverage: both positive effects (through implementation of ecological restoration projects) and negative effects (through urbanization) were observed.