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Although there is an extensive literature covering
traffic sign detectionFrecognition and localization with
potential applications in intelligent transportation sys-
temrdevelopment of a practical automated traffic sign
recognition system remains a challenge. Many factors
affect traffic sign detection. Rust and faded paintr
sign bendingr weather conditions (light or overcast)T
shadowrocclusionsrreflection of sunlight motionrand
vibrations of the van affect image quality. And within
an imagerif the size of a sign is too smalirexisting vi
sion algorithms may treat the sign as noise. While
many techniques for color segmentation have been
suggested!? segmentation remains difficult due to the
abundance of colors in traffic scenes and the influence
of weatherHighting conditions and shadows.
Most developed algorithms detect signs from image
sequences using color segmentation and shape extrac-
tionrthat isl?edge detectionFHough transformPor tem
plate matching. They then match extracted features
with traffic sign models to recognize and identify road
signs.
Traffic signs consist mainly of artificial pure colors:
redT oranger yellowr brownr greenr black and white.
We therefore propose a fuzzy color segmentation algo
rithm to extract these artificial colors. In one traffic
sign libraryPabout one-sixth are black and whiterfor
instancer a white background with black text or ar
rows or a black background with white text or arrows.
To detect white and black traffic signsTone visual cue
is shape information and another is text information.
We make use of text regions (the high contrast be
tween foreground symbols and a panel background)
to reduce the search space for black and white sign
detection. Moreoverrtraffic signs are usually mounted
on poles or lamp posts. This suggests searching for
vertical poles or lines and then searching for possible
traffic signs on them.
In the next section 3Tan architecture for the auto
mated traffic signs recognition system for mobile map
ping is depicted. In section 4Ta color segmentation al
gorithm and a blob analysis algorithm are presented.
In section 5rshape analysis based on Fourier descrip
tors is made. In section 6Tan algorithm for text re
gions extraction based on texture energy is discussed.
3 Overview of the traffics sign
recognition system
The traffic sign detectionTpredicationlYecognition and
location system depicted in Figure 2 consists of four
modules: (i) sign detectionr (ii) sign predictionT (iii)
Figure 2: A traffic sign recognition system
sign recognitionTand (iv) sign location. This article
describes an implementation of the first one.
4 Color segmentation algorithm
To overcome difficulties of designing a general color
segmentation algorithm [6]r we give a special algo
rithm to extract color regions from an image. As noted
earlierrtraffic signs are mainly composed of artificial
redT orangeTyellowr greenT and blue colors. In con
trast to segmenting a natural scene with millions of
possible colorsPwe need only focus on artificial colors
to improve traffic sign detection.
4.1 Color space
A color can be defined as a mixture of tristimulus
components. Many color representation spaces are
in use todayrsuch asTRGBTHSLTand La*b*. Be
cause of lighting conditionsrsigns under shadows are
different from non-shadowed ones. Normalized RGB
color space partially overcomes this drawback. It does
not give an invariant uniform shifting of RGB compo
nents. Other color spaces are often considered. They
consist of chromatic components (hue and saturation)
and an intensity component. Chromatic components
are noise sensitive. For exampleTin the HSL color
spaceTthe H and S values of black and white traffic
signs are very sensitive to lighting conditions.
