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The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part B6b. Beijing 2008
during the imaging stage; the second is produced in re-sampling
or compressing process; the last is determinant, referring to
noises that are caused by the difference of extracted features to
non-extracted features. So, we should smooth the image by
smoothing filter, which could reduce the former two kinds of
noises and make different physical feature in accordance with
different gray distribution region, thus facilitate the feature
discrimination and extraction. In this paper, we utilize median
filter to achieve the goal. Through repetitive tests, 3X3
template proves to be effective in eliminating small vehicles on
roadsides in the imagery. At the meantime, this method is
simple, quick and automatic, hence the advantage of applying
to high spatial resolution images of huge volumes.
Then, clustering algorithm is used to identify road classes. The
key parameter is the number of spectral clusters K into which a
scene is classified. Many researches have done on the selection
of K value, while in this paper, we adopt automatic K-mean
Clustering algorithm to classify the image simply into two
classes, one of which contains road information. Advantages of
such clustering method are obvious: the method is higher in
automation, less sensitive to initial conditions, and costs less
computational expenses. Most importantly, as shadows on roads
are classified into the class containing road information, the
method ensures the road continuity. For non-road speckles or
patches within the road class, they can be eliminated
commendably in the next stage.
2.3 Road Connection Algorithm
In order to extract roadside in spite of heavy shadows on roads,
we bring forward a new algorithm named “road connection
algorithm”. This is the key procedure of the whole frame work,
in which spectral and geometric features of roads are
represented in two rules: (1) spectral feature: for each pixel,
only when its three radiometric properties are similar to those of
roads, it can be identified as road candidates. (2) geometric
feature: on high resolution image, roads are usually smooth
with no small wiggles. Thus in an appropriate distance, road
segments, including smooth curves, can be recognized as
straight line segments.
According to road geometrical properties mentioned above, for
each pixel on the image, search in specific direction in a straight
line at fixed step. If the proportion of road candidate pixels
(refers to pixels whose spectral property satisfies the road) to all
pixels on the line exceeds a threshold value S that we give in
advance, all pixels on the line L could be identified as road
pixels. After that, we convert original non-road pixels to road
pixels.
Assume the image after rough classification as I, and the result
after road connection algorithm as RI, and the value of number
1 marks road. Then the pseudo codes are as follows:
Pro Road Extract (I, L, R)
W = image width, H = image height
For i = 1 to H do begin
For i = 1 to W do begin
For 9 = 0 to 180 by 15 do begin
DL -> pixels on the line segments starting from (ij) in 0
direction with length L
RN-> number of pixels in DL in image RI whose value
equal 1
If RN ^ 1 then continue
End if
In this paper, we take Beijing city as a study case and the data
we utilize is multi-band QUICKBIRD image. In order to
evaluate the result, we define an assessment system according
to information in the imagery and achieved a satisfactory result.
The approach has proved to be simple, quick, automatic and
efficient.
The remainder of this paper is organized as follows. The
automatic road extraction framework which includes the rough
classification, road connection and result grooming is
introduced in section 2. In section 3, we utilize this method to
extract road from QUICKBIRD image and give the accuracy
assessment. At last, conclusions are presented in section 4.
2. METHODOLOGICAL FRAMEWORK
The approach includes both spectral and geometric constraints
about roads network in urban areas. The methodological
framework contains three steps: rough classification, road
connection, and result grooming.
2.1 Road Feature Analysis
In high spatial resolution remotely sensed images, urban roads
have following properties:
Stability of spectral property: The spectral properties of
uncovered roads are stable to a certain degree. Because urban
roads are mainly constructed by asphalt or cement, especially
asphalt dominates a large part; spectral properties of roads are
limited to a fixed range which corresponds to the spectral range
of road materials. However, in the imagery, objects on
roadsides like zebra crossings, cars and people cause noises due
to the huge spectral difference to roads.
Continuity of roads: Normally roads in reality are continuous
and regular in geometry, while in the imagery, trees and
shadows of high buildings by roads interrupt the continuity of
roads to a large degree. But on the whole, roads in the imagery
still have impressive connection and regularity.
Straightness: On high spatial resolution images, urban roads
are straight and smooth with no small wiggles thus can be
recognized as combinations of straight road segments.
Topological property: Road segments are always connected
with each other constituting road networks, and impossible to
be broken suddenly.
2.2 Rough Classification
The first step is rough classification, which enhances the
exploitation potential of spectral content for automated road
extraction.
Firstly, after atmospheric and geometric correction, we need to
pre-process images to eliminate noises in the imagery. For high
spatial resolution satellite images, there are primarily three
types of noises: the first is called white noise that is formed
