International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
boundary exists, it might be reflected by vegetation phe- 
nology. 
In this study, we mainly focused on two points: 1) using 
remote sensing to investigate the spatial patterns of veg- 
etation phenology in the NATT area; 2) try to identify 
the abrupt change (breakpoint) in terms of the phenolog- 
ical metrics along the latitude in the NATT, thus provid- 
ing a phenological perspective on the biogeographical 
boundary question. Our study showed that there were 
significant spatial patterns of vegetation phenology in 
the NATT during past decades, a north-south directional 
trend was identified. Meanwhile, breakpoint analysis 
showed that, there was a distinguishable 'breakpoint' lo- 
cated around 18 °S to 20°S, 
2 DATA AND METHODS 
2.1 Study area 
  
4 Howard Spaings A sets. 
    
-15 — 
-20 d 
-25 - 
S 
o 
-30 - 
Latitude 
-35 d 
  
  
  
7 1 T T 
120 130 140 150 
Longitude °E 
Figure 1: The spatial extent of the NATT study area 
(gray colour area) 
This study focussed on Northern Australia Tropical Tran- 
sect which was extended in this study as a 1.38 million 
km? area which located between latitude 12° S and 23° 
S and between longitude 128 ° E and 138 ° E (Fig. 1). 
The use of transects has been largely adopted by global 
change community over past two decades as a standard 
method to assess spatial patterns of biogeochemical pro- 
cesses (Koch et al., 1995). The spatial variation of long 
time constants along the transect can be used as an sur- 
rogate of predicted temporal variation to understand the 
future responses to global change (Koch et al., 1995). 
The Northern Australian Tropical Transect (NATT) was 
established under IGBP (International Geosphere Bio- 
sphere Programme) in the mid 1990s, and is one of three 
transects around world to study global savannas (Koch 
et al., 1995). Along the NATT, mean annual precipita- 
tion decreases from nearly 1700mm in the north wet end 
(Howard Springs) to 300mm in the south dry end (Alice 
Springs) (Hutley et al., 2011). The vegetation in NATT 
is a wet-dry savannas gradient where in northern half of 
NATT, the dominant vegetation is tropical savannas cov- 
ered by overstory evergreen Eucalyptus and understory 
annual and perennial C4 grasses (Egan and Williams, 
1996). However, in southern half of the NATT the dom- 
inance of savannas declines, and the dominance of Aca- 
cia woodlands and shrub lands and hummock grasslands 
increases. (Bowman and Connors, 1996). 
2.2 Data 
2.2.1 MODI3CI1 EVI A total of more than 11 years 
(2000-2011) of MODIS Terra 16-day 0.05 ° spatial reso- 
lution collection 5 vegetation indices product (MOD13C1) 
were used in this study. This product is mainly de- 
signed to provide globally consistent vegetation condi- 
tions (Running et al., 1994, Justice and Vermote, 1998). 
In this study, the Enhanced Vegetation Index (EVI) was 
used as a surrogate for vegetation growth condition. EVI 
can effectively reduce the soil background and atmo- 
spheric noise while improving the sensitivity in high 
biomass regions (Huete et al., 2002). The equation of 
EVIis: 
  
Dnir — Pred 
EVI=2.5 % 1 
Pnir + 6 x Pred — 7.5 X Pblue = 1 ( ) 
where PNIR, Pred, and ppiue are the wavelengths in the 
near infrared, red, and blue bands respectively (Huete et 
al., 2002). 
The residual cloud and aerosol contamination in the orig- 
inal EVI time series were filtered out based on the qual- 
ity assurance (QA) flags provided along with the MOD13C1 
product. 
For pixels without distinct seasonality, such as deserts 
and water-bodies, no phenology metrics were derived. 
QA filtered data was temporally gap filled by the av- 
erage value of the six points before and after the gap. 
Remaining noise was removed by a Savitzky-Golay fil- 
ter. 
2.3 Methods 
2.3.1 Phenological metrics retrieval method In this 
study, each increase (green-up) and decrease (brown- 
down) during a growing season was reproduced by two 
separate four parameters logistic function: 
b—a 
an 1 + exp(==*) e 
Y = 
where, a is the background EVI before or after growing 
season, b is the maximum EVI during growing season, c 
is the inflection point when the fitted curve reached the 
maximum rising or decreasing speed, d is the scaling 
factor which determines the rate of increase or decrease 
of EVI at inflection point. The parameters were esti- 
mated based on nonlinear least squares criteria for each 
pixel and each phenological cycle during 2000-2011, a 
total of 11 growth cycles. 
The phenological transition dates were determined based 
on the curvature change rate K' of the fitted curve fol- 
lowed Zhang's method (Zhang et al., 2003). Specifi- 
cally, Start of Season (SOS) corresponded to the timing