This paper describes edge detection as a composition of four steps: co
nditioning, feature extraction, blending, and scaling, We examine the
role of geometry in determining good features for edge detection and i
n setting parameters for functions to blend the features, We find that
: 1) statistical features such as the range and standard deviation of
window intensities can be as effective as more traditional features su
ch as estimates of digital gradients; 2) blending functions that are r
oughly concave near the origin of feature space can provide visually b
etter edge images than traditional choices such as the city-block and
Euclidean norms; 3) geometric considerations can be used to specify th
e parameters of generalized logistic functions and Takagi-Sugeno input
-output systems that yield a rich variety of edge images; and 4) under
standing the geometry of the feature extraction and blending functions
is the key to using models based on computational learning algorithms
such as neural networks and fuzzy systems for edge detection, Edge im
ages derived from a digitized mammogram are given to illustrate variou
s beets of our approach.