Test (3) T, or T5 > 275°K to exclude 
clouds and sensor noise (damaged 
pixels) 
Test (4) pj, p2 < 5-6 % to prevent 
false detections by highly reflective 
surfaces 
Where T3, T, and T; represent the top of atmosphere 
(ToA) brightness temperatures (K) for channel 3, 4 
and 5 respectively, pi, p2 the % ToA reflectance in 
channel 1 and 2 respectively while a; is the 
brightness temperature threshold for test i = 1, 2, 3, 
4 and 5. 
However, the GAC images are spatial sub-sample 
produced from the original Local Area Coverage 
(LAC) images. The spatial resolution of GAC data 
is effectively 4.4 km x 1.1 km with a 2.2 km gap 
between each scan line. This spatial degradation of 
GAC data may result in a bias of the derived fire 
information for Borneo (Belward and Lambin, 
1990). Therefore, the capability of GAC data in 
  
  
  
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fire count in LAC 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
active fire detection was examined in relation to that 
of LAC data. Thirteen pairs of LAC, and the 
corresponding GAC data from the same orbit, were 
collected for the 1997-98 El Niño related year. 
Since the data volume of the original LAC images is 
15 times larger than the contemporaneous GAC 
product, in order to create an analogous GAC fire 
count comparable to the LAC fire product, the GAC 
derived fire counts were multiplied by a factor of 
15. 
Results showed that the adjusted GAC fire count 
numbers were very well related to the LAC fire 
counts of the coincident imagery (r^ = 0.99, n = 13 p 
< 0.001) (Figure la). The mean percentage 
difference between the two fire count datasets was — 
1.6% with a standard deviation of 13.9%. Taking 
into account the substantial degradation of LAC 
data during the GAC production, these variations 
are minor, indicating the efficacy of GAC data for 
providing quantitative fire information in Borneo 
during El Nifio periods when the fire occurrence is 
high. 
(b 
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Figure 1 (a) Regression analysis between LAC and adjusted GAC fire counts during El Niño period. (b) 
Temporal evolution of Niño 3 anomaly during the five El Niño events studied herein. It is clearly indicated 
the two strongest El Niño events of 1982-83 and 1997-98, these having the highest absolute anomaly values. 
These data were obtained from the Climate Prediction Centre of the NOAA National weather Service in 
USA. 
The fire counts detected in each GAC image were 
further adjusted for different cloud cover and 
observation time of each GAC image (Kaufman ef 
al., 1990; Giglio et al., 2000). The GAC derived fire 
activity in Borneo for the five El Nifio events from 
1982 to 1998 is showed in Figure 2. Obviously, 
there is a distinct interannual constant pattern of fire 
activity. The major fire activity tends to occur 
between August-October (1* fire sub-season) of the 
first year (Year 0), and between February-April (2 
fire sub-season) of the following year (Year 1). The 
only pronounced exception was the 1993-94 fire 
event when the major fire activity appeared in the 
3d fire sub-season (August-October of Year 1), 
most likely associated with prolonged ENSO 
anomalies (i.e. 1991-92). On the contrary, in 
November-January (NDJ) and March-July (MJJ) of 
the El Nifio period, the fire activity appeared 
significantly weakened, revealing the domination of 
local climate conditions driven by the monsoon 
597 
circulation. As it is depicted in Figure 1b, during 
NDJ of Year 0 and MJJ of Year 1, the ENSO index, 
in most of the studied El Niño events, remained 
high enough to trigger fire occurrence. However, the 
Asian monsoon system is active over Borneo during 
these time periods, particularly during the NDJ of 
Year 0 when the winter (west) monsoon is 
substantially stronger than the summer (east) 
monsoon, resulting strong convection over that 
region. This is also supported by the fact that 
although El Niño is being in its mature phase during 
NDJ of Year 0 (MJJ of Year 1) and the ENSO index 
is very high, moving (or just start to decrease) 
towards to (away from) the peak, negligible fire 
activity occurred. On the contrary, during the MJJ of 
Year 0, El Niño was still not fully developed, while 
in NDJ of Year 1, El Niño was already demised, 
contributing (resulting) in this way, together with 
the strong winter monsoon influence, to the almost 
complete absence of major fire events.