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for the MODIS land product image format conversion and 
coordinates transformation. 
2.3 Spatial Data Preparation and Analyses 
This study is conducted according to three major phases. The 
three major phases comprises of data dissemination, data 
reproduction and transformation and finally data analyses. 
Figure 2 illustrate the processes involved in retrieving albedo. 
MODIS LBl 
MRT TOOLS: 
CONVERSION AND 
TRANSFORMATION 
      
    
     
  
     
       
   
MODIS Li 
MCDA2A? 
  
   
LAXER STACKING 
AND ADDITIONAL OFFSET 
AND MULTIPLY FACTOR 
    
  
  
  
    
LAYER STACKING 
    
         
  
      
  
    
     
TO USE r- 
FRACTION OF 
DIFFUSE 
SKYLIGHT VALUE 
   
  
  
ATMOSPHERIC 
CORRECTION: FLAASH, 55 
CODE, MODTRAN 
   
  
   
SUBSET FILL VALUE: 
23.676, BSA AND WSA 
  
        
  
TO USE: Whitz-sk» Albadg * [optical 
dapth, solar zanith anelz. azrosol t-p2, 
band) — Black-sk- Albado* {1 - Koptical 
dapth, solar zsnith anzla, azrosol t-p2, 
band) 
TOUSE LIANG' S 
MODEL 
     
LAND SURFACE 
ALBEDO :L53) 
Figure 2. Albedo Retrieval Processes 
The yearly and seasonal variations of land surface albedo for 
the study are is derived according to the following steps: 
1. The MODIS data (MCD43A3) were projected into 
WGS84 and converted into GeoTIFF format and 
Binary format using the MRT tools. 
2. The Black Sky Albedo (BSA) and White Sky Albedo 
(WSA) were then stacked into separate. 
3. The fraction of diffuse skylight (s) is identified using 
pre-determined lookup table and simulated 
beforehand using the 6S code. The five parameters 
needed to perform the simulation are as follows 
(Wang et al. 2011; Zhao et al. 2001). 
4. Geometrical Condition (value of solar zenith and 
azimuthal angle, satellite zenith and azimuthal angle 
and Julian Calendar of satellite revisit) 
5. Atmospheric Model (tropical, mid latitude etc.) and 
Aerosol Model Type (LUT AOT550) 
6. Ground and Sensor Altitude (0 represents ground 
surface and -1000 for sensor onboard satellite at 
outside atmosphere) 
7. Spectral bands (MODIS 500m 7 Bands data is pre- 
defined in 6S Model) 
8. Surface Reflectance Characteristics (homogeneous 
and non-uniform surface) 
9. The statistical of multi-temporal surface albedo were 
calculated. 
10. Visualization and Mapping 
Based on BSA, WSA and the s (fraction of diffuse skylight) 
determined in previous steps, the actual albedo can be 
calculated according to (Zhang et al. 2010). 
p =(1-s[6,7(2)}pair ^ s[8.c(A)]odif () 
where p  -the actual albedo 
s =the fraction of diffuse skylight 
© = Solar Zenith Angle 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
T = atmospheric optical depth 
A = wavelength 
pdir = the Black Sky Albedo 
pdif =the White Sky Albedo 
The s value in this study is based on the Fresnel Reflectance 
coefficient light (Jerlov, 1976) which is set to 0.06 
(Ambarwulan, 2010). The designs of analyses are based on 
daily, yearly and according to Malaysia's Monsoon (Monthly) 
variation. Malaysia seasonal breakdown are as Table 1. 
  
  
  
  
  
Monsoon Period Characteristics 
Northeast Nov- Winds 10-20 knots upto 30 Knots during 
Mar cold surges period affecting east coast 
region. 
Heavy Rainfall 
Inter- Apr- Frequent Period of Thunderstorm in 
monsoon May afternoon and evening hour with heavy 
Oct - rainfall causing flash flood. 
Nov 
Southwest May- Winds below 15 knots affecting west coast 
Sept region. 
Drier weather. 
  
  
  
Table 1. Monsoon regimes in Malaysia. (MMD,(Shafie, 2009)). 
3. ANALYSIS AND DISCUSSIONS 
The analyses for this study are separated into three types of 
series i.e. diurnally, yearly and according to monsoons. Tropical 
country like Malaysia received extensive variation of weather 
condition. Daily average will overshadow these effects as it will 
suppress the highest and lowest condition. This will eliminate 
the most remarkable and significance condition one can find. 
The yearly analyses show the impact of land use and land cover 
changes with respect to the yearly average albedo in Malaysia. 
While the monsoon analyses enable us to recognise the albedo 
behaviour and its pattern changes with respect to the local 
climate condition and subsequently it's dynamic towards local 
weather parameters. The following paragraphs will explain the 
results of these analyses. 
3.1 Result 1: The Time-series Analyses (Daily) 
The average daily albedo of maximum and minimum value from 
2000-2009 is 0.254144 and 0.002025 respectively. Though, the 
highest daily albedo marked at 0.37566 at day 145 in 2005 and 
the lowest daily albedo value is 0.00005 at day 41 in 2004. The 
variation of daily albedo in terms of its maximum value shows 
varies distribution over the years. As illustrated in Figure 3, 
there is no certain linear trend of albedo for day 1 until day 361. 
It can be inferred that this values are influences by the surface 
properties, monsoon variation and also the diffusion of skylight. 
This graph is plotted using real reflectance values not the daily 
average values. 
8 Days Time-Series Albedo 2000 - 2009 
ann OQ 0 eee 200 1 o 2002 mme 200 3 2004 
  
2007 2008 2009 
  
oa 
0.35 
a3 
0.25 
0.2 f 
015} 
Albedo 
  
0.05 | 
o 
1 17 33 49 65 B1 9/ 113129 115 167 177 293 209 225211 25 / 273 289 305 321 337 353 
Day of Year 
  
  
  
Figure 3. Daily Albedo 2000 - 2009