International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
cover (i.e. higher increase, lower decrease, etc) according to a 
threshold that indicates a specific degree of certainty. In the 
third phase, the boundaries of local zones within a given urban 
region (e.g. urban blocks, census tracts, zip codes) are used to 
average the magnitudes of change in each land cover type from 
the pixels that fall within individual zones. Next, landscape 
metrics are applied to these zonal averages to quantify the 
ecological patterns of a given magnitude of change in a given 
land cover within a given local zone. The calculated metrics can 
then be used to compare urban local areas in terms of the 
ecological patterns of change associated with urban 
densification and other drivers of internal morphological change 
in urban areas. The following sections outline in more detail the 
nethods used in the three phases described above. 
2.2 MESMA 
Spectral mixture analysis (SMA) (Adams et al., 1993) is one of 
the techniques proposed to provide a solution to the problem of 
mixed pixels in urban satellite imagery with medium spatial 
resolution (i.e. 20m or lower). Findings from recent studies 
indicate that although SMA provides superior results to 
traditional per-pixel classification techniques when applied to 
urban imagery, a considerable degree of error may be 
associated with SMA models (Ward et al., 2000; Rashed et al., 
2001; Small, 2001). This is because the standard SMA model 
implements an invariable set of endmembers to model the 
spectra in all the pixels within an image. This assumption fails 
to account for the fact that, due to the diversity of urban 
materials, the number and type of components within the 
satellite sensor's field of view are variable. Roberts et al. (1998) 
proposed a solution to this problem by developing a modified 
SMA algorithm that allows the number and type of 
endmembers to vary for each pixel in an image. This technique 
is referred to as multiple endmember spectral mixture analysis 
or MEMSA. Thus, MESMA can be described as a modified 
linear SMA approach in which many simple SMA models are 
first calculated for each pixel in the image. The objective is then 
to choose, for every pixel in the image, which model amongst 
the candidate models provides the best fit to the pixel spectrum 
while producing physically reasonable fractions (Roberts et al., 
1998; Rashed et al., 2003). 
The procedure of applying MESMA to urban satellite imagery 
is described in detail in Rashed et al (2003). However, it is 
worthwhile to highlight here some important aspects of this 
procedure to provide a context for the case study described in 
this paper. Applying MESMA to a single-date image starts by 
selecting a set of candidate endmembers believed to represent a 
relatively pure spectral response of the target materials in the 
scene. A conceptual framework for urban landscape ecology 
devised by Ridd (1995) becomes very useful in this regard. 
Ridd suggested that urban areas may be described in terms of 
proportions of Vegetation (V), Impervious surfaces (I), and Soil 
(S) The process of endmember selection is commenced by 
applying the Pixel Purity Index (PPI) method, developed by 
Boardman et al. (1995), to screen all the pixels in the image in 
terms of their relative purity. In the next step, a series of 
standard SMA models are applied based on a variety of possible 
combinations of the selected endmembers. The performance of 
all models is evaluated so that a smallest subset of candidate 
models can be selected for every pixel in the image. A reliable 
candidate model is one that produces physically realistic 
fractions (i.e. 0-100965 range) and does not exceed a certain 
threshold of error. From the selected candidate models, an 
optimal model is then identified for each pixel based on the 
classical maximal covering problem, originally introduced by 
Church and ReVelle (1974). Finally, the fraction values 
produced by these optimal models are utilized to map the 
abundance of general land cover components in the urban scene 
at a given point of time. 
The final results from applying MESMA to each single-date 
image are validated using aerial photos, following a process 
described in Peddle et al. (1999). In this process, a stratified 
adaptive cluster sampling (SACS) method is used to identify a 
number of test sites on the aerial photos. The accumulation of 
corresponding endmember fractions is calculated to estimate the 
area of a test site based on the land cover fractions modeled by 
MESMA. The accuracy of each endmember fraction is 
estimated as the mean of the absolute difference (%) between 
actual and modeled cover estimates derived from aerial photos 
and MESMA, respectively. 
2.3 Change Analysis through Fuzzy Logic 
Fuzzy methods in remote sensing have received growing 
interest in recent years (Foody, 1999; Foody, 2001). This paper 
presents a methodology in which fuzzy models operate in a 
subservient role to MESMA models. The application of fuzzy 
logic to quantifying magnitudes of urban land cover change is 
highly appealing because. of its capability to deal with 
uncertainties such as in the case when one cannot accurately 
identify a threshold value to separate areas of change from areas 
of no-change. Fuzzy logic is a superset of Boolean logic that 
has been extended to handle the concept of partial truth values 
between “certainly true” and “certainly false.” Fuzzy sets are 
sets without sharp boundaries in which the transition between 
membership and non-membership is gradual (Zadeh, 1975). 
This gradient corresponds to the degree to which an element 
(e.g. a pixel) is compatible with the concept represented by a 
fuzzy set. Thus, elements may belong to the fuzzy set to a 
greater or lesser degree as indicated by a larger or smaller 
membership grade. 
Once MESMA fractions are calculated for each individual date, 
change can be identified in a straightforward way by 
subtracting each class of land cover fractions at Date 1 from 
their corresponding fractions at Date 2. The resultant fractional 
differences represent the temporal change in land cover 
abundance in each pixel in absolute terms. To assess the 
magnitude of this temporal change, the proposed methodology 
applies fuzzy sets representing varying degrees of change (high 
increase, lower decrease, etc). This “fuzzification” of change 
involves two steps. The first is to translate the concept of 
magnitude of change into fuzzy sets using sigmoidal (or S- 
curve) membership functions, which are very effective in 
modeling continuous, nonlinear phenomena (Cox, 1999). The 
case study described in this paper utilizes five fuzzy sets 
representing the following levels of change: higher increase, 
lower increase, no change, lower decrease, and higher decrease. 
The equations used to generate these functions are listed and 
discussed in Rashed et al. (2004). The second step of the 
fuzzification process is to apply these fuzzy sets to the ‘change- 
in-fraction images,” which represent change in endmember 
fractions. This step results in new images representing the five 
magnitudes of change in each land cover class on a pixel-by- 
pixel basis. 
2.4 Landscape Metrics 
Landscape metrics are indices developed for categorical map 
patterns. Their development has been based on both information 
theory and fractal geometry (Herold et al., 2002). Categorical 
map patterns represent data in which the ecosystem property of 
interest is represented as a mosaic of patches. Patches represent 
504