In: Wagner W., Szekely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
SURFACE TEMPERATURE ESTIMATION USING ARTIFICIAL NEURAL NETWORK
M. R. Veronez 3 G. Wittmann a , A. O. Reinhardt b , R. M. Da Silva 3
a Graduate Program in Geology, Remote Sensing and Digital Cartography Laboratory, Vale do Rio dos Sinos
University (UNISINOS), Av. Unisinos, 950, CEP 93022-000, Säo Leopoldo, RS, Brazil veronez@unisinos.br
KEY WORDS: Artificial Neural Networks; image from NOAA satellite; surface temperature, split window
ABSTRACT:
This research presents an alternative method to extrapolation land Surface Temperature (ST) through artificial neural network, using
positional variables (UTM coordinates and altitude), temperature and air relative humidity. The study region was the Rio dos Sinos
Hydrographic Basin (BHRS), in Rio Grande do Sul state, Brazil. For training the neural network was used a thermal image from
NOAA satellite, with pixel size of 1X1 km, with known ST information referring to 12/06/2003. After training many network sets
were done and one of them with the best performance and composed by a single intermediate layer (with 4 neurons and logistic
sigmoid activation function) was selected. The training network was tested inside the BHRS where were collected 60 points of ST
values supported by a portable laser sensor on date 3/18/2008. The average error provided by this model for ST measurement was
2.2°C and through executed statistical tests was possible to verify that not exist variation between average ST values accepted as true
and the values provided by the neural model with a significance level of 5%.
1. INTRODUCTION
Artificial Neural Networks (ANN) are organized and
interconnected collections of processing units (neurons or
nodes), whose operation is analogue to a neural structure of
intelligence organisms (Müller and Fill, 2003). ANN extract its
computational power from its solid parallel distribution
structure and ability to leam/generalize, allowing the resolution
of complex propositions in many knowledge areas (Haykin,
2001).
ANN execution is inspired on human brain (Haykin, 2001) and
has been used in many applications with success. In agreement
with Galväo et al. (1999), by the reason of its nonlinear
structure the ANN can acquire more complex data
characteristics, which are not always possible using traditional
statistical techniques.
According to Müller and Fill (2003), conventional methods
don’t have the necessity to know the problem intrinsic theory
and also don’t need to analyze relations that aren’t totally
known between involved variables in modeling, so ANNs have
a greater advantage over them.
Surface Temperature (ST) is established by a fenologic
parameter that is significantly influenced by climate variations
and is an indicator of plants hydrous state. Therefore its
estimation has a large utility to surveys that need to assure the
observation of hydrous culture demand, contributing in a
significative way the irrigation programs (Silva, 2007).
Currently a mostly used method to ST estimation is through the
use of thermal satellite images. Rivas (2004) recommends the
use of NOAAAVHRR (National Oceanic Atmospheric
Administration/Advanced Very High Resolution Radiometer)
images adapted to split windows equation to estimate ST
values. Such modeling connects emissivity variables and
atmospherical data. Is a complex method because beyond it
processes not simple statistical models, it has the necessity to
work with digital images in the emissivity determination
process.
So is much important to have methods of ST estimation in a
more convenient way as, for example, the combination of
temperature, air relative humidity and geographical data
position (Veronez et al., 2006).
Some authors realized researches using ANNs with the finality
of ST estimation based on climate elements (Yang et al., 1997;
Atluri et al., 1999; George, 2001; Veronez et al., 2006; Mao &
Shi, 2008), where all of them have found satisfactory results.
Yang (1997) describe the importance to develope a model
capable to assist agricultural processes, once that ST estimation
in distinct depths is complex due its large number of involved
variables. The author have used as ANN input the following
variables: daily precipitation, evapotranspiration, air maximun
and minimun temperature and days of year, been all these
information easy to obtain on meteorological station.
Atluri (1999) has modeled through ANNs the humidity and soil
ST with the Levemberg-Marquardt algorithm and after many
tests he obtained an accuracy estimation of 98.7% with these
variables. The same author describes the importance to establish
an efficient system to extrapolate such information, once that
these variables are required by distinct geosciences areas.
George (2003) describes the importance of usage ANNs to
estimate soil surface temperature using easy access data.
Thinking on it Veronez et al. (2006) proposed the ANN usage to
model such variable using only positional information (East and
North UTM coordinates), altitude and air average temperature.
The network was established through a supervised training,
where ST information was extracted from NOAA satellite
images.
The results found by Veronez et al. (2006) show that is possible
to extrapolate ST values on distinct periods from NOAA image
processing date using as ANN input a variable that changes with
the time. For the specific case of this research the used variable
was air average temperature. The ST processing was based on
NOAA satellite image with a surface coverage from 6/12/2003.
ST values were extrapolated on 10/8/2005 and the model
validation was accomplished in a municipality urban area
located on Rio dos Sinos Hydrographic Basin (BHRS). The
authors collected ST information with a laser thermometer and
compared them with values provided by ANN, having an
average error less than 2.3°C.
Although some researches aim to simplify the input data on ST
estimation process, is understood that exist another options to
be learned using climate data associated with thermal images.
So the purpose of this research was propose an ANN aiming to
