In: Wagner W., Szekely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
552
DERIVING WATER FRACTION AND FLOOD MAP WITH THE EOS/MODIS DATA
USING REGRESSION TREE APPROACH
D. L. Sun 3 , Y. Y. Yu b
a Department of Geography and Geoinformation Sciences, George Mason University
Fairfax, VA 22030,USA (dsun@gmu.edu)
b NOAA/NESDIS, Center for Satellite Applications and Research, Camp Spring, MD 20746, USA -
yunyue .yu@noaa. go v
KEY WORDS: Regression Tree, Flood, MODIS, Water fraction
ABSTRACT:
This study investigates how to derive water fraction and flood map from the Moderate-Resolution Imaging Spectroradiometer
(MODIS) onboard the Earth Observing System (EOS) using a Regression Tree (RT) approach. The RT approach can integrate all
the possible candidate predictors, such as the MODIS channel 2 reflectance (CH2), reflectance ratio (CH2/CH1), reflectance
difference (CH2-CH1) between MODIS channels 2 and 1, vegetation and water indices. Meanwhile, it provides accuracy estimates
of the derivation. The recent floods in New Orleans area in August 2005 were selected for the study. MODIS surface reflectance
with the matched surface water fraction data were used for the RT training. From the training set, 60% were used for training, and
the remaining 40% for test. Rules and regression models from the RT training were applied for real applications to New Orleans
flooding in 2005 to calculate water fraction values. Flood distributions in both space and time domains were generated using the
differences in water fraction values after and before the flooding. The derived water fraction maps were evaluated using higher
resolution Thematic Mapper (TM) data from the Landsat observations. It shows that correlation between the water fractions derived
from the MODIS and TM data is 0.97, with difference or “bias” of 2.16%, standard deviation of 3.89%, and root mean square error
(rmse) of 4.45%. The results show that the RT approach in dynamic monitoring of floods is promising.
1. INTRODUCTION
Satellite-derived flood maps in near-real time are vital to stake
holders and policy makers for disaster monitoring and relief
efforts. Precise mapping of floods and standing water is also
required for detecting deficiencies in existing flood control and
for damage claims.
Satellite sensors used in river and flood studies may be
classified into two types: (1) passive, in which the sensor
receives energy naturally reflected by or/and emitted from the
earth's surface; and (2) active, in which the sensor provides
illumination and records the amount of incident energy returned
from the sensed surface (Smith, 1997). Sample passive sensors
in visible and infrared spectrums are the Thematic Mapper
(TM) and Multi-Spectral Scanner (MSS) onboard the Landsat
satellites, the Advanced Very High Resolution Radiometer
(AVHRR) onboard NOAA polar-orbiting meteorological
satellites, Visible High Resolution (HRV) sensor onboard the
Satellite Pour l'Observation de la Terre (SPOT), the Advanced
Spacebome Thermal Emission and Reflection Radiometer
(ASTER) and the Moderate-Resolution Imaging
Spectroradiometer (MODIS) onboard the Earth Observation
System (EOS) satellites. Passive microwave radiometers, such
as the Special Sensor Microwave/Imager (SSM/I) on board the
defense meteorological satellites, can transpire clouds and
measure the microwave energy naturally emitted from the
Earth's surface. The coarse spatial resolution of these
microwave sensors (ca. 27 km at 37 GHz) has been mitigated
through the combined use with the visible and infrared sensors
for the flood detection (Hallberg et al., 1973; Sipple et al.,
1992; Toyra et al., 2001; 2002).
Much of the pioneering work on the remote sensing of floods
was accomplished using the MSS sensor on the First Earth
Resources Technology Satellite, later renamed Landsat-1.
With a spatial resolution of about 80 m, MSS data was
used to mapping the extent of flooding in Iowa (Hallberg et al.,
1973; Rango and Salomonson, 1974), Arizona (Morrison and
Cooley, 1973), Virginia (Rango and Salomonson, 1974) and
along the Mississippi River (Deutsch et al., 1973; Deutsch, and
Ruggles, 1974; Rango and Anderson, 1974; McGinnis and
Rango, 1975; Deutsch, 1976; Morrison and White, 1976). All
of these studies show that MSS band 7 (0.8-1.1 pm) was the
most useful for separating water from dry soil or vegetated
surfaces due to the strong absorption of water in the near-
infrared range. This feature was further confirmed by analyzing
MSS band 5 (0.6-0.7 pm), band 7 and field spectral radiometer
data along shoreline water-wet soil-dry soil transitions by Gupta
and Banerji (Gupta and Banerji 1985). Flooded areas were
delineated based on the sharp contrast between water spread
and adjacent areas. The standing water areas appeared as dark
blue to light blue depending upon the depth of water, while the
receded water and wet areas appeared as dark to light gray.
Other studies have continued the methodology developed
with the MSS, using Landsat TM and SPOT data (France and
Hedges, 1986; Jensen et al., 1986; Watson, 1991; Blasco et al.,
1992; Pope et al., 1992; da Silva, 1992). The coarser spatial
resolution (ca. 1 km) sensors, such as the AVHRR, have been
successfully used for studying large river floods (Ali et al.,
1989; Gale and Bainbridge, 1990; Rasid and Pramanik, 1993).
Sheng et al. (2001) summarized the spectral characteristics
of the main features (i.e. water, vegetation, soil, and clouds)
during floods at the observation scale of NOAA satellites.
Although AVHRR data can be displayed in 3-channel color
