Special Section on Advances in Remote Sensing for Monitoring Global Environmental Changes

Variation and trends of landscape dynamics, land surface phenology and net primary production of the Appalachian Mountains

[+] Author Affiliations
Yeqiao Wang

University of Rhode Island, Department of Natural Resources Science, Kingston, Rhode Island 02881

Jianjun Zhao

University of Rhode Island, Department of Natural Resources Science, Kingston, Rhode Island 02881

Northeast Normal University, School of Urban and Environmental Sciences, Changchun, Jilin 130024, China

Yuyu Zhou

Pacific Northwest National Laboratory/University of Maryland, Joint Global Change Research Institute, 5825 University Research Court, Suite 3500, College Park, Maryland 20740

Hongyan Zhang

Northeast Normal University, School of Urban and Environmental Sciences, Changchun, Jilin 130024, China

J. Appl. Remote Sens. 6(1), 061708 (Dec 17, 2012). doi:10.1117/1.JRS.6.061708
History: Received July 11, 2012; Revised November 2, 2012; Accepted November 29, 2012
Text Size: A A A

Open Access Open Access

Abstract.  The gradients of elevations and latitudes in the Appalachian Mountains provide a unique regional perspective on landscape variations in the eastern United States and southeastern Canada. We reveal patterns and trends of landscape dynamics, land surface phenology, and ecosystem production along the Appalachian Mountains using time series data from Global Inventory Modeling and Mapping Studies and Advanced Very High Resolution Radiometer Global Production Efficiency Model datasets. We analyze the spatial and temporal patterns of the normalized difference vegetation index (NDVI), length of growing season (LOS), and net primary production (NPP) of selected ecoregions along the Appalachian Mountains regions. We compare the results in different spatial contexts, including North America and the Appalachian Trail corridor area. To reveal latitudinal variations, we analyze data and compare the results between the 30°-to-40°N and the 40°-to-50°N latitudes. The result reveal significant decreases in annual peak NDVI in the Appalachian Mountains regions. The trend for the Appalachian Mountains regions was a 0.0018 (R2=0.55, P<0.0001) NDVI unit decrease per year during 25 years from 1982 to 2006. The LOS was prolonged by 0.3daysperyear1 during the 25-year percent. The NPP increased by 2.68gCm2yr2 from 1981 to 2000.

Figures in this Article

The Appalachian Mountains, also known as the Appalachians, are a system of mountains in eastern North America. They run from central Alabama to the New England region of the northeast United States and extend into sections of Quebec, New Brunswick, and Newfoundland in Canada. The mountain range forms a natural barrier between the eastern coastal regions and the interior lowlands of northeastern America. The forests of the Appalachians sustain a variety of ecosystems and native biological diversity. The environmental effects and ecosystem functions and services associated with the Appalachians have long been the focus of scientific research in understanding the mountain range as a unique geographic entity and in comparison with different spatial contexts for providing a regional reference and validation.

The Appalachian Trail is an iconic footpath that traverses high-elevation ridges of the Appalachian Mountains. The trail extends over 3500 km across 14 states in the eastern United States from Springer Mountain in northern Georgia to Mount Katahdin in central Maine. The gradients in elevation, latitude, and moisture sustain a rich biological assemblage of temperate zone forest species. The north-south alignment of the Appalachian Trail corridor represents a cross-section mega-transect of the eastern U.S. forests and alpine areas and provides a barometer for early detection of undesirable changes in the natural resources, such as development encroachment, acid precipitation, invasions of exotic species, and climate change impacts.1,2

Climate change studies reveal the effects of global warming on the growing season of terrestrial vegetation at middle and high latitudes.3,4 Over the 20th century, the global average surface temperature increased 0.6±0.2°C. Observable warming occurred between 1976 and 2000, and temperatures are projected to increase5,6 by 1.4°C to 5.8°C from 1990 to 2100. Tracking variations in landscape dynamics provides an understanding of the changing environment, the impacts and threats caused by changes, and the likely trends in the future for natural resources and associated ecosystems.7 Time series remote sensing data provide necessary observations in revealing patterns of landscape dynamics either by abrupt change or gradual variations.

The normalized difference vegetation index (NDVI) has been effectively used for monitoring vegetation dynamics. Consistent and long time-series NDVI data are important for analysis of vegetation responses to global change in terrestrial ecosystems.8 The Global Inventory Monitoring and Modeling Studies (GIMMS) NDVI dataset derived from Advanced Very High Resolution Radiometer (AVHRR) has been broadly used for studying vegetation activity on regional and global scales.

Phenology studies have long been reported in different domains, such as climate change.9 biodiversity,10 wildlife ecology,11 snow dynamics,12 fire effects,13 and crops.14 Land surface phenology (LSP) is one of the measures of landscape dynamics. It reflects the response of vegetated surfaces to seasonal and annual changes in the climatic and hydrologic cycle. LSP is strongly linked to climatic factors.15 It has been broadly studied in the context of ecosystem responses to climate change16 and for monitoring and understanding global change in vegetation lifecycle events. Because of spatial resolution of remote sensing data, LSP is described as an indicator of mixtures of land covers and is distinct from traditional notion of species-centric phenology, such as seasonal flowering or budburst.17,18 Because LSP is based on remote sensing observations at regional and global scales, it serves as a key biological indicator for detecting the response of terrestrial ecosystems to climatic variation.

LSP metrics are primarily based on time series images of vegetation indices from optical sensors such as AVHRR, spot-vegetation (VGT), and moderate resolution imaging spectroradiometer (MODIS). These metrics typically retrieve the time of the onset of greenness as the start of the season (SOS), onset of senescence or time of end of greenness as the end of the season (EOS), timing of the maximum of the growing season by peak vegetation indices, and the length of growing season (LOS) or duration of greenness. An increasing number of studies have reported the shifts in timing and length of the growing season based on phenology, satellite data, and climatological studies.6

Net primary production (NPP) plays an important role in the Earth surface system’s health19 and the terrestrial carbon cycle.20,21 NPP and its response to climate change have been the focus of global change research.22 Studies have been conducted based on historical datasets.2332 Recent climatic changes have enhanced plant growth in northern middle and high latitudes.31 Various NPP models have been developed to analyze NPP response to climate change.3242 Regional scale carbon cycle processes and climate patterns provide indications of potential responses and feedback to climate change.43

Other studies showed that temperatures across the northeastern United States have been increasing steadily since the 1970s. A wide range of indicators in the Northeast have already been observed to be responsive to the changes, which in turn have the potential to impact urban and rural life, agriculture, industry, tourism, and natural ecosystems.44 The U.S. Global Change Research Program reported that the annual average temperature in the Northeast has increased by 1.1°C, with winter temperatures rising twice that much, since 1970. At the same time, warming has resulted in many other climate-related changes, including more frequent days with temperatures above 32.2°C, longer growing seasons, increased heavy precipitation, more winter precipitation falling as rain instead of snow, reduced snowpack, earlier breakup of winter ice on lakes and rivers, and earlier spring snowmelt resulting in earlier peak river flows and rising sea surface temperatures and sea levels.45 Projections along the Appalachian Trail corridor area showed a steady temperature increase ranging from 2°C to 6°C by the end of the 21st century. Precipitation, however, did not show any significant trend or decadal variation.46

Therefore, the objective of this study is to investigate the patterns and trends of NDVI, LSP, and NPP of the Appalachian Mountains regions and make comparisons of those variables with different scales of spatial contexts using time series GIMMS and Global Production Efficiency Model (GloPEM) datasets.37,47

Study Areas

The selected Appalachian Mountains regions consist of four provinces of ecoregions in the United States and Canada covering a latitudinal range between 34°4N and 49°15N and 406,944km2 in area (Fig. 1). The provinces of ecoregions include the Adirondack-New England Mixed Forest-Coniferous Forest-Alpine Meadow Province, the Eastern Broadleaf Forest Province, and the Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province in the United States48 and a section of the Eastern Canadian Forests.

Graphic Jump LocationF1 :

The study area consists of four provinces of ecoregions along the Appalachian Mountains in the eastern United States and southeastern Canada. The selected Appalachian Mountains ecoregion provinces include (A) Eastern Canadian Forests, (B) Adirondack-New England Mixed Forest-Coniferous Forest-Alpine Meadow Province, (C) Eastern Broadleaf Forest Province, and (D) Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province. North America and an Appalachian Trail corridor area are selected for the comparative studies.

The Adirondack-New England Mixed Forest-Coniferous Forest-Alpine Meadow Province has a modified continental climatic regime with long, cold winters and warm summers. Annual precipitation is evenly distributed. The landscape is mountainous and was previously glaciated. Forest vegetation is a transition between boreal on the north and broadleaf deciduous to the south. The Eastern Broadleaf Forest Province has a continental-type climate of cold winters and warm summers. Annual precipitation is greater during the summer. Topography is variable, ranging from plains to low hills of low relief along the Atlantic coast. Interior areas are high hills to semi-mountainous, parts of which were glaciated. Vegetation is characterized by tall, cold-deciduous broadleaf forests. The Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province is a moderately dissected plateau of irregular plains and open hills. Geologic formations are mostly marine deposits of limestones, shales, and sandstone. The existing land cover type is mainly agricultural and urban. Small areas of natural cover types remain, consisting of forests of oak-hickory, maple-beech-birch, and oak-gum-cypress cover types. The Eastern Canadian Forests are characterized by forested land in eastern Quebec, much of Newfoundland, the highlands of New Brunswick, and Cape Breton Island, Nova Scotia. The climate ranges from high and mid-boreal and perhumid mid-boreal to Oceanic, Atlantic, and maritime mid-boreal. Summers are generally cool, with average temperatures ranging from 8.5°C in the north to 14.5°C in the south. Winter temperatures vary according to the proximity to the ocean and continental landmass.

In order to reveal the differences and similarities of NDVI, SOS, and NPP in the Appalachian Mountains regions, we compared the variables in different spatial scales with North America and the Appalachian Trail corridor area (Fig. 1), and in different latitudinal ranges from 30°N to 40°N and 40°N to 50°N in North America.

Datasets

GIMMS49 data derived from AVHRR have been used extensively for global-scale vegetation monitoring and detection of trends in vegetation conditions.50 GIMMS data provide global time series NDVI measurements at a spatial resolution of 8×8km2. The data are composited over a period of approximately 15 days with the maximum value compositing (MVC) technique51 to reduce cloud cover and to maintain temporal frequency. The data have been corrected for calibration, view geometry, volcanic aerosols, and other effects not related to vegetation change.49,5255 GIMMS data have been used broadly in LSP studies.15,5663 The GIMMS data were fitted yearly with a Gaussian function to generate smoothed data for each of the 25 years from 1982 to 2006. We used monthly composites of GIMMS data to calculate the LSP metrics. The NPP dataset estimated by AVHRR GloPEM was designed to run with both biological and environmental variables derived.37,47 The GloPEM dataset is available from 1981 to 2000 in 10-day periods or a summed annual level. The dataset is derived from AVHRR images at an 8-km resolution from the AVHRR Pathfinder Project.

Land Surface Phenology Metrics

The methods to obtain LSP metrics include thresholds, derivatives, smoothing functions, and fitted models.64 The TIMESAT software program65,66 is among those widely used12,13,6770 In order to reduce dropouts or gaps from long time-series data, TIMESAT uses Savitzky-Golay filtering, asymmetrical Gaussian, or double logistic functions for fitting NDVI data.71 The local Savitzky-Golay function can capture subtle and rapid changes in the time series, but it is also sensitive to noise. The asymmetrical Gaussian and double logistic functions are less sensitive to the noise and can derive a better description of the beginnings and endings of the seasons.65,72 In this study, we adopted the asymmetrical Gaussian approach: Display Formula

g(t;x1,x2,x3,x4,x5)={exp[(tx1x2)x1]ift>x1exp[(x1tx4)x5]ift<x1,(1)
where x1 determines the position of the maximum or minimum with respect to the independent time variable t, x2 and x3 determine the width and flatness (kurtosis) of the right half function, and x4 and x5 determine the width and flatness of the left half function.2,71

In order to make comparisons of LSP in different scales, we employed the GIMMS and the phenology data from the USDA Forest Service that possess 231-m spatial resolution and cover the time period from 2003 to 2006. We then determined the parameter. The SOS is defined as the time for which the left edge has increased to 20% (seasonal amplitude from minimum NDVI to maximum NDVI) measured from the left minimum NDVI. The EOS is defined as the time for which the right edge has decreased to 20% (seasonal amplitude from minimum NDVI to maximum NDVI) measured from the right minimum NDVI. The LOS is the time period measured in days from the SOS to the EOS. We built the smooth time series of NDVI from TIMESAT. We derived the LSP metrics based on and adopted the adaptation strength of 2.0, no spike filtering, and amplitude. We calculated the SOS and EOS for each year and obtained LOS as the difference between SOS and EOS in each grid cell. In this paper, we analyzed the spatial and temporal variation of LOS in the study areas. We used the nonparametric Mann-Kendall test for testing the presence of the monotonic increasing or decreasing trends and the Sen’s method for estimating the slope of linear trends of annual peak values of NDVI, LOS, and NPP.

Spatial Pattern Of NDVI, LSP, and NPP

Figure 2 illustrates spatial patterns of the mean value of peak NDVI, LSP, NPP, Temperature, Precipitation, and Land Cover. The peak NDVI, LSP, and NPP represent the maximum value of the year and were obtained using the MVC method. The mean peak NDVI, LSP, and NPP were obtained similarly. Land cover types were considered in obtaining the spatial variation of NDVI, as shown in Fig. 2(a) and 2(f). For example, forests are mainly distributed in humid climatic zones of the Appalachian Mountains73 and therefore possess high NDVI values. At pixel scale, the data illustrate spatial dynamics of LOS of the Appalachian Mountains between 1982 and 2006. The spatial variation indicates that the average LOS varied from 144 to 262 days, and extended LOS was observed in low-latitude areas, as shown in Fig. 2(b). The patterns indicate that LOS increased from northeast to southwest in these areas. Spatial pattern reveals that LOS was more responsive to the variation of temperature [Fig. 2(d)] than to precipitation [Fig. 2(e)]. Annual mean NPP ranged from 450 to 1,541gCm2yr1 [Fig. 2(c)] in the Appalachian Mountains over the 20 years from 1991 to 2000. NPP values reflected the latitudinal effects from southwest to northeast at 34°N to 40°N, 40°N to 45°N, and 45°N to 50°N. Areas with low NPP were found in the high-latitude regions, consistent with the changes in temperature [Fig. 2(d)]. The pattern of temperature variation showed a decreasing trend from southwest to northeast. The mean temperature showed high values from 34°N to 40°N, medium values from 40°N to 45° N, and low values from 45°N to 50°N. The precipitation was highest with 2,181mm/year in the low-latitude regions, as shown in Fig. 2(e). In the southwestern region, the NPP, temperature, and precipitation measures were higher than those in other regions. A combination of higher temperature and precipitation contributes to high NPP in the southwestern region of the Appalachian Mountains.

Graphic Jump LocationF2 :

The spatial patterns of mean peak NDVI, LSP, NPP, Temperature, Precipitation, and Land Cover of the studied Appalachian Mountains regions.

Trends Of NDVI, LSP, and NPP

The trend of NDVI in the Appalachian Mountains regions varied from 0.012 to 0.0056 units. The declining trends of peak NDVI occurred in the Appalachian Mountains, particularly in the central regions [Fig. 3(a)]. Only the section area within the Eastern Canadian Forests showed increasing trends of peak NDVI.

Graphic Jump LocationF3 :

Trends in peak NDVI, LOS, and NPP within the selected Appalachian Mountains regions from 1982 to 2006.

Spatial variations in LOS trends indicate that LOS varied between 2.34 days (decreasing) to 2.97 days (increasing) per year from 1982 to 2006 over the Appalachian Mountains regions [Fig. 3(b)]. The decreasing trends (<1daysyr1) were mainly found in the Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province and the Eastern Canadian Forests. Positive LOS trends mainly occurred in the Adirondack-New England Mixed Forest-Coniferous Forest-Alpine Meadow Province, as shown in Fig. 3(b).

We calculated the trends in NPP at the pixel level (8 km) from 1981 to 2000 using linear least squares. These calculations are shown in Fig. 3(c). Positive and negative NPP trends were found across the Appalachian Mountains regions. Observable increases occurred in the Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province and the Northeastern Mixed Forest Province. A decrease in NPP occurred in the northeast, and an increased trend was observed in the southwest of the Appalachian Mountains.

Comparison of Appalachian Mountains with Different Spatial Contexts

The NDVI data were calculated for vegetated area only. For Figs. 456, the straight lines were generated using the method of linear least squares. Significant decrease in annual peak NDVI was observed in the Appalachian Mountains, as well as the Appalachian Trail corridor area (Fig. 4). The average slope in the Appalachian Mountains was a 0.0018 (R2=0.55, P<0.0001) NDVI unit decrease per year during the 25 years from 1982 to 2006. For the Appalachian Trail corridor area, the average slope was a 0.0022 (R2=0.62, P<0.0001) NDVI unit decrease per year over the 25 years. However, there was no observable trend in North America or in the selected latitudinal ranges from 30°N to 40°N and from 40°N to 50°N (Fig. 4 and Table 1).

Graphic Jump LocationF4 :

The interannual variability of NDVI for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°–50°N range in North America, and the Appalachian Trail corridor area between 1982 and 2006.

Graphic Jump LocationF5 :

The variation of LOS for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°N–50°N range in North America, and the Appalachian Trail corridor area.

Graphic Jump LocationF6 :

The variation in NPP for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°N–50°N range in North America, and the Appalachian Trail corridor area.

Table Grahic Jump Location
Table 1.The parameters of NDVI, LOS, and NPP

The prolonged LOS was 0.3dayyr1 over the entire Appalachian Mountains, 0.39dayyr1 in latitudinal zone from 40°N to 50°N, 0.02dayyr1 in North America, and 0.28dayyr1 in the Appalachian Trail corridor area. However, the LOS trend was shortened by 0.06dayyr1 in latitudes from 30°N to 40°N. Although there was no indication of a significant trend in LOS in any region during the study time periods, abnormal values in some years (e.g., 1998 and 1999) were observable against the calculated mean values and are shown in Fig. 5.

We calculated the annual mean NPP values for the Appalachian Mountains, North America, and the Appalachian Trail corridor area (Fig. 6 and Table 1). The average NPP values were 1,008, 797, 597, 802, and 876gCm2yr1, in the 30°N–40°N range, the 40–50°N range, North America, the Appalachian Mountains, and the Appalachian Trail corridor area, respectively. The increasing trend in NPP was observed for all the regions during the 20-year period (Fig. 6). The NPP increased 2.68gCm2yr2 (R2=0.24, P=0.016) from 1982 to 2006 in Appalachian Mountains. The trends in NPP showed an increase of 5.80gCm2yr2 (R2=0.43, P<0.0009) in the 30°N–40°N range, 4.44gCm2yr2 (R2=0.37, P=0.0025) in the 40°N–50°N range, 2.85gCm2yr2 (R2=0.39, P=0.002) in North America, and 2.17gCm2yr2 (R2=0.25, P=0.015) in the Appalachian Trail corridor.

This study revealed the spatial and temporal variations and trends in landscape dynamics, LSP, and NPP in the study area. The comparisons examined the Appalachian Mountains as a unique geographic entity and their topographic and elevation effects in the spatial context. Our conclusions are as follows.

The peak NDVI values decreased significantly in the Appalachian Mountains and the Appalachian Trail corridor area (Fig. 4). Both trends possessed higher negative slopes than those in the 30°N–40°N and 40°N–50°N latitudinal zones and North America. The mean peak NDVI values were 0.86 in the Appalachian Mountains and 0.84 in the Appalachian Trail corridor, higher than those of North America. Other studies have suggested that the average annual peak NDVI presented a declining trend over many protected areas in North America.50 Given that neither temperature nor precipitation showed a correlation with NDVI, this may imply that the observed decrease in NDVI was mainly driven by the combination of urban expansion and outbreaks of hemlock wooly adelgids (Adelges tsugae)7476 and other insect pests. Consistent with the patterns observed in the AVHRR GIMMS data along the Appalachian Trail corridor, analyses using other types of remote sensing data have shown a decrease in forest cover in the eastern U.S., mainly due to the growth of urban areas since the 1970s.7,7779

There are different results from different methods for calculation of LSP parameters.64 For example, the results from four methods were very much different. The SOS calculated by the moving average method was the lowest, and the EOS value was the highest, but the derivative method delivered the highest SOS value and the lowest EOS value.

A reported LSP study suggested that the EOS in North America was delayed by 8.1 days per decade from 1982 to 1999 and by 1.3 days per decade from 2000 to 2008.80 Another study reported that SOS advanced by approximately 8 days, EOS was delayed by 4 days, and LOS increased by 12 days in North America from 1982 to 1999.81 The results of this study suggested that LOS in the Appalachian Mountains advanced 7.5 days from 1982 to 2006. The longest annual mean LOS value (233 days) was observed in the Appalachian Trail corridor area, and the second longest LOS value (227 days) was observed in the Appalachian Mountains regions. The mean LOS in the latitudinal range between 40°N and 50°N increased by 0.39daysyr1 (R2=0.11, P=0.056) from 1982 to 2006; that increase was higher than those in other regions. The overall trend along the Appalachian Mountains, despite local variations, agreed with broader patterns obtained for the Northern Hemisphere and North America. The local variations were caused by topographic and elevation effects, as well as associated land cover types and ecosystems.

To further understand the effect of elevation, we divided the LOS into 20 categories from 5m to 2,025 m. We found that the LOS was shortened by 1.2 days (R2=0.86, P<0.001) for every 100-m increase in elevation. The prolonged LOS was mainly attributed to delayed EOS. This study concluded that the variations and trends of LSP metrics in the Appalachian Mountains were comparable to those obtained for the Appalachian Trail corridor area.82 The LOS anomalies in 1987, 1994, and 1998 followed the pattern of warm and cold episodes based on a threshold of +/0.5°C for the Oceanic Niño Index (ONI). The reversed LOS patterns correspond to El Niño in 1997 to 1998 and La Niña in 1999 to 2000 events.83 This indicates that LOS is sensitive to climate variations.

NPP modeling studies have documented that terrestrial photosynthetic activity has increased over the past two to three decades in the middle and high latitudes in the Northern Hemisphere.2830,32,84 The mean annual NPP in North America (north of 22°N) was reported as 6.2PgCyr1, increasing by 0.028PgCyr2 (significant at the 99% level) from 1982 to 1998.28 The results from this study illustrated significant increasing trends of NPP from 1981 to 2000 in all the study regions. The NPP in the Appalachian Mountains increased by 2.68gCm2yr2 (R2=0.24, P=0.017), a smaller rate than that for North America (2.85gCm2yr2, R2=0.39, P=0.002). The largest annual mean NPP value (1009gCm2yr1) and the largest trend increase (5.8gCm2yr2, R2=0.43, P=0.0009) were observed in the latitudinal range between 30°N and 40°N. The mean NPP in the Appalachian Trail corridor area increased by 3.23gCm2yr2 (R2=0.25, P=0.015), which was larger than that for North America and smaller than that for the Appalachian Mountains regions.

While prolonged LOS and increasing trends of annual NPP were observed in the Appalachian Mountains and the Appalachian Trail corridor, peak NDVI showed a decreasing trend. There are many factors that could affect the change of NDVI, LOS, and NPP in different spatial contexts of the study areas. The similar pattern of variations and trends between the Appalachian Trail corridor area and the Appalachian Mountains regions suggested that the Appalachian Trail corridor area can serve as a mega-transect to reflect such variations and trends of the Appalachian Mountains regions.

This study was funded by NASA Science Mission Directorate (ROSES-2008) Decision Support through Earth Science Research Results under the project “A Decision Support System for Monitoring, Reporting and Forecasting Ecological Conditions of the Appalachian National Scenic Trail” (Grant NNX09AV82G). In particular, the authors thank the contributions of those who are on the project team to develop the decision support system: Peter August, Roland Duhaime, Christopher Damon, John Clark, Fu Luo, Charles LaBash, and Peter Paton from the University of Rhode Island; Forrest Melton, Hirofumi Hashimoto, Samuel Hiatt, and Ramakrishna Nemani from the NASA Ames Research Center; Fred Dieffenbach, Matt Robison, Casey Reese, and Brian Mitchell from the National Park Service; Ken Stolte from the USDA Forest Service; Glenn Holcomb and Marcia McNiff from the USGS; and Paul Mitchell from the Appalachian Trail Conservancy. Dr. William Hargrove of the Eastern Forest Environmental Threat Assessment Center, USDA Forest Service, provided the 231-m spatial resolution phenology data. The authors wish to express their sincere appreciation for the critiques and suggestions from anonymous reviewers that helped improve the quality of the manuscript.

Dufour  C., Crisfield  E., eds., The Appalachian Trail MEGA-Transect. ,  Appalachian Trail Conservancy ,  Harpers Ferry, WV  (2008).
Zhao  J. et al., “The variation of land surface phenology from 1982 to 2006 along the Appalachian Trail,” IEEE Trans. Geosci. Rem. Sens.. 51, (4 ) (2013), CrossRef. 0196-2892 
Myneni  R. B. et al., “Increased plant growth in the northern high latitudes from 1981 to 1991,” Nature. 386, (6626 ), 698 –702 (1997), CrossRef. 0028-0836 
Zhang  X. et al., “The footprint of urban climates on vegetation phenology,” Geophys. Res. Lett.. 31, (12 ), L12209  (2004), CrossRef. 0094-8276 
Houghton  J. T. et al., eds., Climate Change 2001: The Scientific Basis: Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. (2001).
Linderholm  H. W., “Growing season changes in the last century,” Agric. Forest Meteorol.. 137, (1–2 ) 1 –14 (2006), CrossRef. 0168-1923 
Wang  Y. et al., “Remote sensing of land-cover change and landscape context of the National Parks: a case study of the Northeast Temperate Network,” Rem. Sens. Environ.. 113, (7 ), 1453 –1461 (2009), CrossRef. 0034-4257 
Brown  M. et al., “Neural networks as a tool for constructing continuous NDVI time series from AVHRR and MODIS,” Int. J. Rem. Sens.. 29, (24 ), 7141 –7158 (2008), CrossRef. 0143-1161 
Badeck  F.-W. et al., “Responses of spring phenology to climate change,” New Phytol.. 162, (2 ), 295 –309 (2004), CrossRef. 0028-646X 
Hurlbert  A. H., Haskell  J. P., “The effect of energy and seasonality on avian species richness and community composition,” Am. Natural.. 161, (1 ), 83 –97 (2003), CrossRef. 0003-0147 
Hebblewhite  M., Merrill  E., McDermid  G., “A multi-scale test of the forage maturation hypothesis in a partially migratory ungulate population,” Ecol. Monogr.. 78, (2 ), 141 –166 (2008), CrossRef. 0012-9615 
Jönsson  A. M. et al., “Annual changes in MODIS vegetation indices of Swedish coniferous forests in relation to snow dynamics and tree phenology,” Rem. Sens. Environ.. 114, (11 ), 2719 –2730 (2010), CrossRef. 0034-4257 
Van Leeuwen  W. J. D., “Monitoring the effects of forest restoration treatments on post-fire vegetation recovery with MODIS multitemporal data,” Sensors. 8, (3 ), 2017 –2042 (2008), CrossRef. 0746-9462 
Sakamoto  T. et al., “A crop phenology detection method using time-series MODIS data,” Rem. Sens. Environ.. 96, (3–4 ) 366 –374 (2005), CrossRef. 0034-4257 
Heumann  B. W. et al., “AVHRR derived phenological change in the Sahel and Soudan, Africa, 1982–2005,” Rem. Sens. Environ.. 108, (4 ), 385 –392 (2007), CrossRef. 0034-4257 
Cleland  E. E. et al., “Shifting plant phenology in response to global change,” Trends Ecol. Evol.. 22, (7 ), 357 –365 (2007), CrossRef. 0169-5347 
de Beurs  K. M., Henebry  G. M., “Land surface phenology, climatic variation, and institutional change: Analyzing agricultural land cover change in Kazakhstan,” Remote Sensing of Environment. 89, (4 ), 497 –509 (2004), CrossRef. 0034-4257 
Friedl  M. et al., “Land surface phenology,” A Community White Paper requested by NASA (2006).
Running  S. W., Thornton  P. E., Nemani  R. R., Glassy  J. M., “Global terrestrial gross and net primary productivity from the Earth Observing System,” in Methods in Ecosystem Science. , Sala  O., Jackson  R., Mooney  H., eds.,  Springer-Verlag ,  New York , pp. 44 –57 (2000).
Keeling  C. D., Chin  J. F. S., Whorf  T. P., “Increased activity of northern vegetation inferred from atmospheric CO2 measurements,” Nature. 382, (6587 ), 146 –149 (1996), CrossRef. 0028-0836 
Field  C. B. et al., “Primary production of the biosphere: integrating terrestrial and oceanic components,” Science. 281, (5374 ), 237 –240 (1998), CrossRef. 0036-8075 
Cramer  W. et al., “Comparing global models of terrestrial net primary productivity (NPP): overview and key results,” Global Change Biology. 5, (S1 ), 1 –15 (1999), CrossRef. 1354-1013 
Melillo  J. M. et al., “Global climate change and terrestrial net primary production,” Nature. 363, (6426 ), 234 –240 (1993), CrossRef. 0028-0836 
Malmström  C. M. et al., “Interannual variation in global-scale net primary production: Testing model estimates,” Global Biogeochem. Cycles. 11, (3 ), 367 –392. 0886-6236 CrossRef
Peng  C., Apps  M. J., “Modelling the response of net primary productivity (NPP) of boreal forest ecosystems to changes in climate and fire disturbance regimes,” Ecol. Modell.. 122, (3 ), 175 –193 (1999), CrossRef. 0304-3800 
Schimel  D. et al., “Contribution of Increasing CO2 and Climate to Carbon Storage by Ecosystems in the United States,” Science. 287, (5460 ), 2004 –2006 (2000), CrossRef. 0036-8075 
Lucht  W. et al., “Climatic control of the high-latitude vegetation greening trend and Pinatubo effect,” Science. 296, (5573 ), 1687 –1689 (2002), CrossRef. 0036-8075 
Hicke  J. A. et al., “Satellite-derived increases in net primary productivity across North America, 1982–1998,” Geophys. Res. Lett.. 29, , 4  (2002), CrossRef. 0094-8276 
Cao  M. et al., “Response of terrestrial carbon uptake to climate interannual variability in China,” Global Change Biol.. 9, (4 ), 536 –546 (2003), CrossRef. 1354-1013 
Fang  J. et al., “Increasing net primary production in China from 1982 to 1999,” Front. Ecol. Environ.. 1, (6 ), 293 –297 (2003), CrossRef. 1540-9295 
Nemani  R. R. et al., “Climate-driven increases in global terrestrial net primary production from 1982 to 1999,” Science. 300, (5625 ), 1560 –1563 (2003), CrossRef. 0036-8075 
Piao  S., Fang  J., He  J., “Variations in Vegetation Net Primary Production in the Qinghai-Xizang Plateau, China, from 1982 to 1999,” Climat. Change. 74, (1 ), 253 –267 (2006), CrossRef. 0165-0009 
Goetz  S. J., Prince  S. D., “Remote sensing of net primary production in boreal forest stands,” Agric. For. Meteorol.. 78, (3–4 ), 149 –179 (1996), CrossRef. 0168-1923 
Piao  S. L., Fang  J. Y., Guo  Q.-H., “Application of CASE model to the estimation of Chinese terrestrial net primary productivity,” Acta Phytoecol. Sin.. 25, (5 ), 603 –608 (2001).
Potter  C. S. et al., “Terrestrial ecosystem production: a process model based on global satellite and surface data,” Global Biogeochem. Cycles. 7, (4 ), 811 –841 (1993), CrossRef. 0886-6236 
Prasad  A. K. et al., “Crop yield estimation model for Iowa using remote sensing and surface parameters,” Int. J. Appl. Earth Observ. Geoinform.. 8, (1 ), 26 –33 (2006), CrossRef.
Prince  S. D., Goward  S. N., “Global primary production: a remote sensing approach,” J. Biogeogr.. 22, (4/5 ), 815 –835 (1995), CrossRef. 1365-2699 
Seaquist  J., Olsson  L., Ardö  J., “A remote sensing-based primary production model for grassland biomes,” Ecol. Modell.. 169, (1 ), 131 –155 (2003), CrossRef. 0304-3800 
Sitch  S. et al., “Evaluation of ecosystem dynamics, plant geography and terrestrial carbon cycling in the LPJ dynamic global vegetation model,” Global Change Biol.. 9, (2 ), 161 –185 (2003), CrossRef. 1354-1013 
Tottrup  C., Rasmussen  M. S., “Mapping long-term changes in savannah crop productivity in Senegal through trend analysis of time series of remote sensing data,” Agric. Ecosyst. Environ.. 103, (3 ), 545 –560 (2004), CrossRef.
Wang  B. et al., “Comparison of net primary productivity in karst and non-karst areas: a case study in Guizhou Province, China,” Environ. Earth Sci.. 59, (6 ), 1337 –1347 (2010), CrossRef. 1866-6280 
Zhou  Y. et al., “Observation and simulation of net primary productivity in Qilian Mountain, western China,” J. Environ. Manage.. 85, (3 ), 574 –584 (2007), CrossRef. 0301-4797 
Turner  D. P., Ollinger  S. V., Kimball  J. S., “Integrating remote sensing and ecosystem process models for landscape- to regional-scale analysis of the carbon cycle,” BioScience. 54, (6 ), 573 –584 (2004), CrossRef. 0006-3568 
Hayhoe  K. et al., “Past and future changes in climate and hydrological indicators in the US Northeast,” Climate Dynam.. 28, (4 ), 381 –407 (2007), CrossRef. 0930-7575 
Karl  T. R. et al., Eds., Global Climate Change Impacts in the United States. , 1st ed.,  Cambridge University Press ,  New York  (2009).
Hashimoto  H. et al., “Monitoring and forecasting climate impacts on ecosystem dynamics in protected areas using the terrestrial observation and prediction system,” in Remote Sensing of Protected Lands. , Wang  Y., Ed., pp. 523 –540,  CRC Press ,  Boca Raton, Florida  (2011).
Prince  S., Small  J., “Global Production Efficiency Model, 1997_npp_latlon,” Department of Geography, University of Maryland, College Park, MD (2003).
McNab  W. H. et al., “Description of ecological subregions: sections of the conterminous United States [CD-ROM],” US Department of Agriculture, Forest Service, Washington, DC (2007).
Tucker  C. J., Pinzon  J. E., Brown  M. E., “Global inventory modeling and mapping studies,” NA94apr15b.n11-VIg, 2.0., Global Land Cover Facility, University of Maryland, College Park, MD (2004).
Nemani  R. et al., “Monitoring and forecasting ecosystem dynamics using the Terrestrial Observation and Prediction System (TOPS),” Rem. Sens. Environ.. 113, (7 ), 1497 –1509 (2009), CrossRef. 0034-4257 
Holben  B. N., “Characteristics of maximum-value composite images from temporal AVHRR data,” Int. J. Rem. Sens.. 7, (11 ), 1417 –1434 (1986), CrossRef. 0143-1161 
Pinzon  J., Brown  M. E., Tucker  C. J., “Satellite time series correction of orbital drift artifacts using empirical mode decomposition,” in Hilbert-Huang Transform and its Applications. ,  World Scientific , pp. 167 –186 (2005).
Jolly  W. M. et al., “A flexible, integrated system for generating meteorological surfaces derived from point sources across multiple geographic scales,” Environ. Modell. Softw.. 20, (7 ), 873 –882 (2005), CrossRef.
Tucker  C. J. et al., “An extended AVHRR 8-km NDVI dataset compatible with MODIS and SPOT vegetation NDVI data,” Int. J. Rem. Sens.. 26, (20 ), 4485 –4498 (2005), CrossRef. 0143-1161 
Sobrino  J. A. et al., “NOAA-AVHRR orbital drift correction from solar zenithal angle data,” IEEE Trans. Geosci. Rem. Sens.. 46, (12 ), 4014 –4019 (2008), CrossRef. 0196-2892 
Beck  P. S. A. et al., “Improved monitoring of vegetation dynamics at very high latitudes: a new method using MODIS NDVI,” Rem. Sens. Environ.. 100, (3 ), 321 –334 (2006), CrossRef. 0034-4257 
Brown  M. E., de Beurs  K. M., “Evaluation of multi-sensor semi-arid crop season parameters based on NDVI and rainfall,” Rem. Sens. Environ.. 112, (5 ), 2261 –2271 (2008), CrossRef. 0034-4257 
Stöckli  R., Vidale  P. L., “European plant phenology and climate as seen in a 20-year AVHRR land-surface parameter dataset,” Int. J. Rem. Sens.. 25, (17 ), 3303 –3330 (2004), CrossRef. 0143-1161 
Julien  Y., Sobrino  J. A., “Global land surface phenology trends from GIMMS database,” International J. Rem. Sens.. 30, (13 ), 3495 –3513 (2009), CrossRef. 0143-1161 
White  M. A. et al., “Intercomparison, interpretation, and assessment of spring phenology in North America estimated from remote sensing for 1982–2006,” Global Change Biol.. 15, (10 ), 2335 –2359 (2009), CrossRef. 1354-1013 
Hermance  J. F. et al., “Extracting phenological signals from multiyear AVHRR NDVI time series: framework for applying high-order annual splines with roughness damping,” IEEE Trans. Geosci. Rem. Sens.. 45, (10 ), 3264 –3276 (2007), CrossRef. 0196-2892 
Zhu  W. et al., “A changing-weight filter method for reconstructing a high-quality NDVI time series to preserve the integrity of vegetation phenology,” IEEE Trans. Geosci. Rem. Sens.. 50, (4 ), 1085 –1094 (2012), CrossRef. 0196-2892 
Ito  E. et al., “Leaf-shedding phenology in Lowland Tropical Seasonal Forests of Cambodia as estimated from NOAA satellite images,” IEEE Trans. Geosci. Rem. Sens.. 46, (10 ), 2867 –2871 (2008), CrossRef. 0196-2892 
de Beurs  K. M., Henebry  G. M., “Spatio-temporal statistical methods for modelling land surface phenology,” in Phenological Research. , Hudson  I. L., Keatley  M. R., eds.,  Springer Netherlands ,  Dordrecht , pp. 177 –208 (2010).
Jonsson  P., Eklundh  L., “Seasonality extraction by function fitting to time-series of satellite sensor data,” IEEE Trans. Geosci. Rem. Sens.. 40, (8 ), 1824 –1832 (2002), CrossRef. 0196-2892 
Jönsson  P., Eklundh  L., “TIMESAT—a program for analyzing time-series of satellite sensor data,” Computers & Geosciences. 30, (8 ), 833 –845 (2004), CrossRef.
Bachoo  A., Archibald  S., “Influence of using date-specific values when extracting phenological metrics from 8-day composite NDVI data,” in  Proc. International Workshop on the Analysis of Multi-temporal Remote Sensing Images , pp. 1 –4,  IEEE  (2007).
Hird  J. N., McDermid  G. J., “Noise reduction of NDVI time series: an empirical comparison of selected techniques,” Rem. Sens. Environ.. 113, (1 ), 248 –258 (2009), CrossRef. 0034-4257 
Peppin  D. et al., “Post-wildfire seeding in forests of the western United States: an evidence-based review,” Forest Ecol. Manage.. 260, (5 ), 573 –586 (2010), CrossRef. 0378-1127 
Steenkamp  K. et al., “Long-term phenology and variability of Southern African vegetation,” in  Proc. IEEE International Geoscience and Remote Sensing Symposium , Vol. 3, , pp. III-816 –III-819,  IEEE  (2008).
Eklundh  L., Jonsson  P., TIMESAT 3.0 Software Manual (2010).
Gao  F. et al., “An Algorithm to produce temporally and spatially continuous MODIS-LAI time series,” IEEE Geosci. Rem. Sens. Lett.. 5, (1 ), 60 –64 (2008), CrossRef. 1545-598X 
Zhang  X. et al., “Climate controls on vegetation phenological patterns in northern mid- and high latitudes inferred from MODIS data,” Global Change Biol.. 10, (7 ) 1133 –1145 (2004), CrossRef. 1354-1013 
Orwig  D. A. et al., “Multi-year ecosystem response to hemlock woolly adelgid infestation in southern New England forests,” Can. J. Forest Res.. 38, (4 ), 834 –843 (2008), CrossRef. 0045-5067 
Eschtruth  A. K. et al., “Vegetation dynamics in declining eastern hemlock stands: 9 years of forest response to hemlock woolly adelgid infestation,” Can. J. Forest Res.. 36, (6 ), 1435 –1450 (2006), CrossRef. 0045-5067 
Lovett  G. M. et al., “Forest ecosystem responses to exotic pests and pathogens in Eastern North America,” BioScience. 56, (5 ), 395 –405 (2006), CrossRef. 0006-3568 
Potere  D. et al., “Patterns in forest clearing along the appalachian trail corridor,” Photogram. Eng. Rem. Sens.. 73, (7 ), 783  (2007). 0099-1112 
Drummond  M. A., Loveland  T. R., “Land-use pressure and a transition to forest-cover loss in the Eastern United States,” BioScience. 60, (4 ), 286 –298 (2010), CrossRef. 0006-3568 
Hansen  M. C., Stehman  S. V., Potapov  P. V., “Quantification of global gross forest cover loss,” PNAS. 107, (19 ), 8650 –8655 (2010), CrossRef. 0027-8424 
Jeong  S.-J. et al., “Phenology shifts at start vs. end of growing season in temperate vegetation over the Northern Hemisphere for the period 1982–2008,” Global Change Biol.. 17, (7 ), 2385 –2399 (2011), CrossRef. 1354-1013 
Zhou  L. et al., “Variations in northern vegetation activity inferred from satellite data of vegetation index during 1981 to 1999,” J. Geophys. Res.. 106, (D17 ) 20069 –20083 (2001), CrossRef. 0148-0227 
Zhao  J., Wang  Y., Zhang  H., “Automated batch processing of mass remote sensing and geospatial data to meet the needs of end users,” in  Proc. IEEE International Geoscience and Remote Sensing Symposium , pp. 3464 –3467,  IEEE  (2011).
van der Werf  G. R. et al., “Continental-scale partitioning of fire emissions during the 1997 to 2001 El Nino/La Nina period,” Science. 303, (5654 ), 73  (2004), CrossRef. 0036-8075 
Fang  J. et al., “Changes in forest biomass carbon storage in china between 1949 and 1998,” Science. 292, (5525 ), 2320 –2322 (2001), CrossRef. 0036-8075 

Grahic Jump LocationImage not available.

Yeqiao Wang received his MS and PhD in natural resources management and engineering from the University of Connecticut in 1992 and 1995, respectively. He is currently a professor of terrestrial remote sensing at the Department of Natural Resources Science, University of Rhode Island, USA.

Grahic Jump LocationImage not available.

Jianjun Zhao received his BS in 2007 from the School of Urban and Environmental Sciences, Northeast Normal University, Changchun, China, where he is currently working toward a PhD in remote sensing. He is also currently a visiting PhD student at the Department of Natural Resource Science, University of Rhode Island, USA. His research interests are remote sensing of terrestrial ecosystems, data processing, and applications.

Grahic Jump LocationImage not available.

Yuyu Zhou received his PhD in environmental sciences from the University of Rhode Island, where he studied land use and land cover change and its impact on the environment. He then worked as a postdoctoral research associate at Purdue University and performed high-resolution fossil-fuel CO2 emissions modeling studies at national and city scales. Currently, he is a scientist conducting global climate change research at the Pacific Northwest National Laboratory as part of a diverse, interdisciplinary group of scientists who develop and apply an integrated global land use-energy-economy model.

Grahic Jump LocationImage not available.

Hongyan Zhang received his PhD from the Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences. He is currently a professor in GIS and remote sensing with the School of Urban and Environmental Sciences, Northeast Normal University, Changchun, China. His main research interests are applications of GIS and remote sensing and geoinformatic presentation.

© 2012 Society of Photo-Optical Instrumentation Engineers

Citation

Yeqiao Wang ; Jianjun Zhao ; Yuyu Zhou and Hongyan Zhang
"Variation and trends of landscape dynamics, land surface phenology and net primary production of the Appalachian Mountains", J. Appl. Remote Sens. 6(1), 061708 (Dec 17, 2012). ; http://dx.doi.org/10.1117/1.JRS.6.061708


Figures

Graphic Jump LocationF1 :

The study area consists of four provinces of ecoregions along the Appalachian Mountains in the eastern United States and southeastern Canada. The selected Appalachian Mountains ecoregion provinces include (A) Eastern Canadian Forests, (B) Adirondack-New England Mixed Forest-Coniferous Forest-Alpine Meadow Province, (C) Eastern Broadleaf Forest Province, and (D) Central Appalachian Broadleaf Forest-Coniferous Forest-Meadow Province. North America and an Appalachian Trail corridor area are selected for the comparative studies.

Graphic Jump LocationF2 :

The spatial patterns of mean peak NDVI, LSP, NPP, Temperature, Precipitation, and Land Cover of the studied Appalachian Mountains regions.

Graphic Jump LocationF3 :

Trends in peak NDVI, LOS, and NPP within the selected Appalachian Mountains regions from 1982 to 2006.

Graphic Jump LocationF4 :

The interannual variability of NDVI for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°–50°N range in North America, and the Appalachian Trail corridor area between 1982 and 2006.

Graphic Jump LocationF5 :

The variation of LOS for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°N–50°N range in North America, and the Appalachian Trail corridor area.

Graphic Jump LocationF6 :

The variation in NPP for the Appalachian Mountains, North America, the 30°N–40°N range in North America, the 40°N–50°N range in North America, and the Appalachian Trail corridor area.

Tables

Table Grahic Jump Location
Table 1.The parameters of NDVI, LOS, and NPP

References

Dufour  C., Crisfield  E., eds., The Appalachian Trail MEGA-Transect. ,  Appalachian Trail Conservancy ,  Harpers Ferry, WV  (2008).
Zhao  J. et al., “The variation of land surface phenology from 1982 to 2006 along the Appalachian Trail,” IEEE Trans. Geosci. Rem. Sens.. 51, (4 ) (2013), CrossRef. 0196-2892 
Myneni  R. B. et al., “Increased plant growth in the northern high latitudes from 1981 to 1991,” Nature. 386, (6626 ), 698 –702 (1997), CrossRef. 0028-0836 
Zhang  X. et al., “The footprint of urban climates on vegetation phenology,” Geophys. Res. Lett.. 31, (12 ), L12209  (2004), CrossRef. 0094-8276 
Houghton  J. T. et al., eds., Climate Change 2001: The Scientific Basis: Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. (2001).
Linderholm  H. W., “Growing season changes in the last century,” Agric. Forest Meteorol.. 137, (1–2 ) 1 –14 (2006), CrossRef. 0168-1923 
Wang  Y. et al., “Remote sensing of land-cover change and landscape context of the National Parks: a case study of the Northeast Temperate Network,” Rem. Sens. Environ.. 113, (7 ), 1453 –1461 (2009), CrossRef. 0034-4257 
Brown  M. et al., “Neural networks as a tool for constructing continuous NDVI time series from AVHRR and MODIS,” Int. J. Rem. Sens.. 29, (24 ), 7141 –7158 (2008), CrossRef. 0143-1161 
Badeck  F.-W. et al., “Responses of spring phenology to climate change,” New Phytol.. 162, (2 ), 295 –309 (2004), CrossRef. 0028-646X 
Hurlbert  A. H., Haskell  J. P., “The effect of energy and seasonality on avian species richness and community composition,” Am. Natural.. 161, (1 ), 83 –97 (2003), CrossRef. 0003-0147 
Hebblewhite  M., Merrill  E., McDermid  G., “A multi-scale test of the forage maturation hypothesis in a partially migratory ungulate population,” Ecol. Monogr.. 78, (2 ), 141 –166 (2008), CrossRef. 0012-9615 
Jönsson  A. M. et al., “Annual changes in MODIS vegetation indices of Swedish coniferous forests in relation to snow dynamics and tree phenology,” Rem. Sens. Environ.. 114, (11 ), 2719 –2730 (2010), CrossRef. 0034-4257 
Van Leeuwen  W. J. D., “Monitoring the effects of forest restoration treatments on post-fire vegetation recovery with MODIS multitemporal data,” Sensors. 8, (3 ), 2017 –2042 (2008), CrossRef. 0746-9462 
Sakamoto  T. et al., “A crop phenology detection method using time-series MODIS data,” Rem. Sens. Environ.. 96, (3–4 ) 366 –374 (2005), CrossRef. 0034-4257 
Heumann  B. W. et al., “AVHRR derived phenological change in the Sahel and Soudan, Africa, 1982–2005,” Rem. Sens. Environ.. 108, (4 ), 385 –392 (2007), CrossRef. 0034-4257 
Cleland  E. E. et al., “Shifting plant phenology in response to global change,” Trends Ecol. Evol.. 22, (7 ), 357 –365 (2007), CrossRef. 0169-5347 
de Beurs  K. M., Henebry  G. M., “Land surface phenology, climatic variation, and institutional change: Analyzing agricultural land cover change in Kazakhstan,” Remote Sensing of Environment. 89, (4 ), 497 –509 (2004), CrossRef. 0034-4257 
Friedl  M. et al., “Land surface phenology,” A Community White Paper requested by NASA (2006).
Running  S. W., Thornton  P. E., Nemani  R. R., Glassy  J. M., “Global terrestrial gross and net primary productivity from the Earth Observing System,” in Methods in Ecosystem Science. , Sala  O., Jackson  R., Mooney  H., eds.,  Springer-Verlag ,  New York , pp. 44 –57 (2000).
Keeling  C. D., Chin  J. F. S., Whorf  T. P., “Increased activity of northern vegetation inferred from atmospheric CO2 measurements,” Nature. 382, (6587 ), 146 –149 (1996), CrossRef. 0028-0836 
Field  C. B. et al., “Primary production of the biosphere: integrating terrestrial and oceanic components,” Science. 281, (5374 ), 237 –240 (1998), CrossRef. 0036-8075 
Cramer  W. et al., “Comparing global models of terrestrial net primary productivity (NPP): overview and key results,” Global Change Biology. 5, (S1 ), 1 –15 (1999), CrossRef. 1354-1013 
Melillo  J. M. et al., “Global climate change and terrestrial net primary production,” Nature. 363, (6426 ), 234 –240 (1993), CrossRef. 0028-0836 
Malmström  C. M. et al., “Interannual variation in global-scale net primary production: Testing model estimates,” Global Biogeochem. Cycles. 11, (3 ), 367 –392. 0886-6236 CrossRef
Peng  C., Apps  M. J., “Modelling the response of net primary productivity (NPP) of boreal forest ecosystems to changes in climate and fire disturbance regimes,” Ecol. Modell.. 122, (3 ), 175 –193 (1999), CrossRef. 0304-3800 
Schimel  D. et al., “Contribution of Increasing CO2 and Climate to Carbon Storage by Ecosystems in the United States,” Science. 287, (5460 ), 2004 –2006 (2000), CrossRef. 0036-8075 
Lucht  W. et al., “Climatic control of the high-latitude vegetation greening trend and Pinatubo effect,” Science. 296, (5573 ), 1687 –1689 (2002), CrossRef. 0036-8075 
Hicke  J. A. et al., “Satellite-derived increases in net primary productivity across North America, 1982–1998,” Geophys. Res. Lett.. 29, , 4  (2002), CrossRef. 0094-8276 
Cao  M. et al., “Response of terrestrial carbon uptake to climate interannual variability in China,” Global Change Biol.. 9, (4 ), 536 –546 (2003), CrossRef. 1354-1013 
Fang  J. et al., “Increasing net primary production in China from 1982 to 1999,” Front. Ecol. Environ.. 1, (6 ), 293 –297 (2003), CrossRef. 1540-9295 
Nemani  R. R. et al., “Climate-driven increases in global terrestrial net primary production from 1982 to 1999,” Science. 300, (5625 ), 1560 –1563 (2003), CrossRef. 0036-8075 
Piao  S., Fang  J., He  J., “Variations in Vegetation Net Primary Production in the Qinghai-Xizang Plateau, China, from 1982 to 1999,” Climat. Change. 74, (1 ), 253 –267 (2006), CrossRef. 0165-0009 
Goetz  S. J., Prince  S. D., “Remote sensing of net primary production in boreal forest stands,” Agric. For. Meteorol.. 78, (3–4 ), 149 –179 (1996), CrossRef. 0168-1923 
Piao  S. L., Fang  J. Y., Guo  Q.-H., “Application of CASE model to the estimation of Chinese terrestrial net primary productivity,” Acta Phytoecol. Sin.. 25, (5 ), 603 –608 (2001).
Potter  C. S. et al., “Terrestrial ecosystem production: a process model based on global satellite and surface data,” Global Biogeochem. Cycles. 7, (4 ), 811 –841 (1993), CrossRef. 0886-6236 
Prasad  A. K. et al., “Crop yield estimation model for Iowa using remote sensing and surface parameters,” Int. J. Appl. Earth Observ. Geoinform.. 8, (1 ), 26 –33 (2006), CrossRef.
Prince  S. D., Goward  S. N., “Global primary production: a remote sensing approach,” J. Biogeogr.. 22, (4/5 ), 815 –835 (1995), CrossRef. 1365-2699 
Seaquist  J., Olsson  L., Ardö  J., “A remote sensing-based primary production model for grassland biomes,” Ecol. Modell.. 169, (1 ), 131 –155 (2003), CrossRef. 0304-3800 
Sitch  S. et al., “Evaluation of ecosystem dynamics, plant geography and terrestrial carbon cycling in the LPJ dynamic global vegetation model,” Global Change Biol.. 9, (2 ), 161 –185 (2003), CrossRef. 1354-1013 
Tottrup  C., Rasmussen  M. S., “Mapping long-term changes in savannah crop productivity in Senegal through trend analysis of time series of remote sensing data,” Agric. Ecosyst. Environ.. 103, (3 ), 545 –560 (2004), CrossRef.
Wang  B. et al., “Comparison of net primary productivity in karst and non-karst areas: a case study in Guizhou Province, China,” Environ. Earth Sci.. 59, (6 ), 1337 –1347 (2010), CrossRef. 1866-6280 
Zhou  Y. et al., “Observation and simulation of net primary productivity in Qilian Mountain, western China,” J. Environ. Manage.. 85, (3 ), 574 –584 (2007), CrossRef. 0301-4797 
Turner  D. P., Ollinger  S. V., Kimball  J. S., “Integrating remote sensing and ecosystem process models for landscape- to regional-scale analysis of the carbon cycle,” BioScience. 54, (6 ), 573 –584 (2004), CrossRef. 0006-3568 
Hayhoe  K. et al., “Past and future changes in climate and hydrological indicators in the US Northeast,” Climate Dynam.. 28, (4 ), 381 –407 (2007), CrossRef. 0930-7575 
Karl  T. R. et al., Eds., Global Climate Change Impacts in the United States. , 1st ed.,  Cambridge University Press ,  New York  (2009).
Hashimoto  H. et al., “Monitoring and forecasting climate impacts on ecosystem dynamics in protected areas using the terrestrial observation and prediction system,” in Remote Sensing of Protected Lands. , Wang  Y., Ed., pp. 523 –540,  CRC Press ,  Boca Raton, Florida  (2011).
Prince  S., Small  J., “Global Production Efficiency Model, 1997_npp_latlon,” Department of Geography, University of Maryland, College Park, MD (2003).
McNab  W. H. et al., “Description of ecological subregions: sections of the conterminous United States [CD-ROM],” US Department of Agriculture, Forest Service, Washington, DC (2007).
Tucker  C. J., Pinzon  J. E., Brown  M. E., “Global inventory modeling and mapping studies,” NA94apr15b.n11-VIg, 2.0., Global Land Cover Facility, University of Maryland, College Park, MD (2004).
Nemani  R. et al., “Monitoring and forecasting ecosystem dynamics using the Terrestrial Observation and Prediction System (TOPS),” Rem. Sens. Environ.. 113, (7 ), 1497 –1509 (2009), CrossRef. 0034-4257 
Holben  B. N., “Characteristics of maximum-value composite images from temporal AVHRR data,” Int. J. Rem. Sens.. 7, (11 ), 1417 –1434 (1986), CrossRef. 0143-1161 
Pinzon  J., Brown  M. E., Tucker  C. J., “Satellite time series correction of orbital drift artifacts using empirical mode decomposition,” in Hilbert-Huang Transform and its Applications. ,  World Scientific , pp. 167 –186 (2005).
Jolly  W. M. et al., “A flexible, integrated system for generating meteorological surfaces derived from point sources across multiple geographic scales,” Environ. Modell. Softw.. 20, (7 ), 873 –882 (2005), CrossRef.
Tucker  C. J. et al., “An extended AVHRR 8-km NDVI dataset compatible with MODIS and SPOT vegetation NDVI data,” Int. J. Rem. Sens.. 26, (20 ), 4485 –4498 (2005), CrossRef. 0143-1161 
Sobrino  J. A. et al., “NOAA-AVHRR orbital drift correction from solar zenithal angle data,” IEEE Trans. Geosci. Rem. Sens.. 46, (12 ), 4014 –4019 (2008), CrossRef. 0196-2892 
Beck  P. S. A. et al., “Improved monitoring of vegetation dynamics at very high latitudes: a new method using MODIS NDVI,” Rem. Sens. Environ.. 100, (3 ), 321 –334 (2006), CrossRef. 0034-4257 
Brown  M. E., de Beurs  K. M., “Evaluation of multi-sensor semi-arid crop season parameters based on NDVI and rainfall,” Rem. Sens. Environ.. 112, (5 ), 2261 –2271 (2008), CrossRef. 0034-4257 
Stöckli  R., Vidale  P. L., “European plant phenology and climate as seen in a 20-year AVHRR land-surface parameter dataset,” Int. J. Rem. Sens.. 25, (17 ), 3303 –3330 (2004), CrossRef. 0143-1161 
Julien  Y., Sobrino  J. A., “Global land surface phenology trends from GIMMS database,” International J. Rem. Sens.. 30, (13 ), 3495 –3513 (2009), CrossRef. 0143-1161 
White  M. A. et al., “Intercomparison, interpretation, and assessment of spring phenology in North America estimated from remote sensing for 1982–2006,” Global Change Biol.. 15, (10 ), 2335 –2359 (2009), CrossRef. 1354-1013 
Hermance  J. F. et al., “Extracting phenological signals from multiyear AVHRR NDVI time series: framework for applying high-order annual splines with roughness damping,” IEEE Trans. Geosci. Rem. Sens.. 45, (10 ), 3264 –3276 (2007), CrossRef. 0196-2892 
Zhu  W. et al., “A changing-weight filter method for reconstructing a high-quality NDVI time series to preserve the integrity of vegetation phenology,” IEEE Trans. Geosci. Rem. Sens.. 50, (4 ), 1085 –1094 (2012), CrossRef. 0196-2892 
Ito  E. et al., “Leaf-shedding phenology in Lowland Tropical Seasonal Forests of Cambodia as estimated from NOAA satellite images,” IEEE Trans. Geosci. Rem. Sens.. 46, (10 ), 2867 –2871 (2008), CrossRef. 0196-2892 
de Beurs  K. M., Henebry  G. M., “Spatio-temporal statistical methods for modelling land surface phenology,” in Phenological Research. , Hudson  I. L., Keatley  M. R., eds.,  Springer Netherlands ,  Dordrecht , pp. 177 –208 (2010).
Jonsson  P., Eklundh  L., “Seasonality extraction by function fitting to time-series of satellite sensor data,” IEEE Trans. Geosci. Rem. Sens.. 40, (8 ), 1824 –1832 (2002), CrossRef. 0196-2892 
Jönsson  P., Eklundh  L., “TIMESAT—a program for analyzing time-series of satellite sensor data,” Computers & Geosciences. 30, (8 ), 833 –845 (2004), CrossRef.
Bachoo  A., Archibald  S., “Influence of using date-specific values when extracting phenological metrics from 8-day composite NDVI data,” in  Proc. International Workshop on the Analysis of Multi-temporal Remote Sensing Images , pp. 1 –4,  IEEE  (2007).
Hird  J. N., McDermid  G. J., “Noise reduction of NDVI time series: an empirical comparison of selected techniques,” Rem. Sens. Environ.. 113, (1 ), 248 –258 (2009), CrossRef. 0034-4257 
Peppin  D. et al., “Post-wildfire seeding in forests of the western United States: an evidence-based review,” Forest Ecol. Manage.. 260, (5 ), 573 –586 (2010), CrossRef. 0378-1127 
Steenkamp  K. et al., “Long-term phenology and variability of Southern African vegetation,” in  Proc. IEEE International Geoscience and Remote Sensing Symposium , Vol. 3, , pp. III-816 –III-819,  IEEE  (2008).
Eklundh  L., Jonsson  P., TIMESAT 3.0 Software Manual (2010).
Gao  F. et al., “An Algorithm to produce temporally and spatially continuous MODIS-LAI time series,” IEEE Geosci. Rem. Sens. Lett.. 5, (1 ), 60 –64 (2008), CrossRef. 1545-598X 
Zhang  X. et al., “Climate controls on vegetation phenological patterns in northern mid- and high latitudes inferred from MODIS data,” Global Change Biol.. 10, (7 ) 1133 –1145 (2004), CrossRef. 1354-1013 
Orwig  D. A. et al., “Multi-year ecosystem response to hemlock woolly adelgid infestation in southern New England forests,” Can. J. Forest Res.. 38, (4 ), 834 –843 (2008), CrossRef. 0045-5067 
Eschtruth  A. K. et al., “Vegetation dynamics in declining eastern hemlock stands: 9 years of forest response to hemlock woolly adelgid infestation,” Can. J. Forest Res.. 36, (6 ), 1435 –1450 (2006), CrossRef. 0045-5067 
Lovett  G. M. et al., “Forest ecosystem responses to exotic pests and pathogens in Eastern North America,” BioScience. 56, (5 ), 395 –405 (2006), CrossRef. 0006-3568 
Potere  D. et al., “Patterns in forest clearing along the appalachian trail corridor,” Photogram. Eng. Rem. Sens.. 73, (7 ), 783  (2007). 0099-1112 
Drummond  M. A., Loveland  T. R., “Land-use pressure and a transition to forest-cover loss in the Eastern United States,” BioScience. 60, (4 ), 286 –298 (2010), CrossRef. 0006-3568 
Hansen  M. C., Stehman  S. V., Potapov  P. V., “Quantification of global gross forest cover loss,” PNAS. 107, (19 ), 8650 –8655 (2010), CrossRef. 0027-8424 
Jeong  S.-J. et al., “Phenology shifts at start vs. end of growing season in temperate vegetation over the Northern Hemisphere for the period 1982–2008,” Global Change Biol.. 17, (7 ), 2385 –2399 (2011), CrossRef. 1354-1013 
Zhou  L. et al., “Variations in northern vegetation activity inferred from satellite data of vegetation index during 1981 to 1999,” J. Geophys. Res.. 106, (D17 ) 20069 –20083 (2001), CrossRef. 0148-0227 
Zhao  J., Wang  Y., Zhang  H., “Automated batch processing of mass remote sensing and geospatial data to meet the needs of end users,” in  Proc. IEEE International Geoscience and Remote Sensing Symposium , pp. 3464 –3467,  IEEE  (2011).
van der Werf  G. R. et al., “Continental-scale partitioning of fire emissions during the 1997 to 2001 El Nino/La Nina period,” Science. 303, (5654 ), 73  (2004), CrossRef. 0036-8075 
Fang  J. et al., “Changes in forest biomass carbon storage in china between 1949 and 1998,” Science. 292, (5525 ), 2320 –2322 (2001), CrossRef. 0036-8075 

Some tools below are only available to our subscribers or users with an online account.

Related Content

Customize your page view by dragging & repositioning the boxes below.

Related Book Chapters

Topic Collections

PubMed Articles
Advertisement


 

  • Don't have an account?
  • Subscribe to the SPIE Digital Library
  • Create a FREE account to sign up for Digital Library content alerts and gain access to institutional subscriptions remotely.
Access This Article
Sign in or Create a personal account to Buy this article ($20 for members, $25 for non-members).
Access This Proceeding
Sign in or Create a personal account to Buy this article ($15 for members, $18 for non-members).
Access This Chapter

Access to SPIE eBooks is limited to subscribing institutions and is not available as part of a personal subscription. Print or electronic versions of individual SPIE books may be purchased via SPIE.org.