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USING BACKSCATTER FROM RADAR IMAGES FOR CLASSIFYING AND DETERMINING THE BULK DENSITY OF 
THE URBAN ENVIRONMENT 
Catherine Ticehurst (Ph.D student), Bruce Forster (Professor) & Yunhan Dong (Research Assistant) 
School of Geomatic Engineering 
University of New South Wales 
Sydney NSW 2052 AUSTRALIA 
Ph: 612385 4182 
Fax: 612 313 7493 
Commission VII, Working Group 9 
KEY WORDS: Land Use, Urban, Classification, Radar 
ABSTRACT 
The urban environment is a mixture of buildings (of varying size, shape, and density), and vegetated and non-vegetated 
open spaces. The proportion of each of these characteristics in an area is generally related to its land use. Radar is 
showing potential in assisting classification of the built environment due to its close correlation with the bulk density of 
buildings. However one of the problems with using radar is that the backscatter is particularly sensitive to the radar look 
direction with respect to street orientation. This paper examines this property, and how different aspects of radars 
interaction with the built environment can assist in urban classification. 
INTRODUCTION 
There is a need to classify the environment into its 
various land uses to keep records of a cities size and 
layout. Some cities in developing countries are growing 
rapidly, making it difficult for governments to maintain 
these records by conventional surveying and mapping 
methods. Satellite and airborne radar remote sensing 
provides a relatively cheap and fast method of acquiring 
up-to-date information about the environment, especially 
in regions where cloud and rain may affect visible and 
infrared sensors. Radar images give detail about the 
shape and physical properties of the earth's surface, and 
are showing potential for determining the vertical bulk 
density (as compared to planimetric density from 
visible/infrared sensors) and for the classification of the 
urban environment into its various land uses. 
Although there has been a substantial amount of analysis 
done on radar and the environment, very little has 
concentrated on the urban environment alone. Bryan 
(1982) and Hardaway et al (1982) have analysed radar 
backscatter with respect to urban street orientation and 
showed a strong correlation. Henderson (1985) carried 
out a detailed study using dual-polarised Synthetic 
Aperture Radar (SAR) to classify the urban environment, 
but found the radar had some confusion between classes. 
Deguchi et al (1995) examined the relationship between 
building coverage ratio, from visible/near infrared images, 
and bulk ratio of urban environments, using radar data. 
Forster et al (1996) have also investigated the possibility 
of combining visible/near infrared data of a city, with radar 
information. 
Single polarised data provides limited information 
compared to multipolarised images. Some work has been 
undertaken on quad-polarised radar and polarisation 
Signatures, using them to distinguish between urban, 
park, forest, geology, and ocean. (See for example, 
Fvans et al (1988), Van Zyl et al (1987), and Zebker et al 
(1987)). These studies looked at the urban environment 
I^ a broad sense rather than classification of the built 
environment into all its land uses. A detailed study of the 
types of scattering in the urban environment from 
709 
multipolarised radar by Dong et al (1996) has shown 
some promising results. 
The present study involves examining radars interaction 
with the urban environment so that information about land 
use and the bulk density of the urban area can be derived 
from radar images. The bulk density is related to the 
volume of buildings in a particular region. For example a 
central business district has a higher bulk density than a 
residential area. An initial investigation looks at the 
relationship between radar backscatter and urban land 
use classes (obtained from a SIR-B image over Sydney, 
Australia). A model has been developed to give the 
expected radar backscatter from a block of buildings, and 
its results are also presented. 
RADAR BACKSCATTER IN THE URBAN 
ENVIRONMENT 
Radar transmits a wave of known length, polarisation, 
azimuth direction, and incidence angle. The built 
environment has properties, such as building size, shape, 
orientation with respect to radar, and material (surface 
roughness and dielectric properties including moisture 
content), with which the radiation interacts, and 
determines the properties of the backscattered radar 
response. Radar is particularly sensitive to building "bulk" 
and the orientation of buildings with respect to the radars 
look direction. 
One of the main contributions to radar backscatter in the 
urban environment is due to corner reflections. Double 
bounce corner reflection, or dihedral reflection, occurs 
when the radar look direction is perpendicular to a 
building wall. The radar wave will bounce from the ground 
to the wall and back to the sensor, or vice versa. 
RELATIONSHIP OF LAND USE AND RADAR 
BACKSCATTER 
A preliminary study has been undertaken which involved 
examining SIR-B data (L-band, HH) over a region in the 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996