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distance interval to provide a full coverage of the
road way and its surroundings. By applying
photogrammetric triangulation technology, any
point that appears in both images can be located into
a global coordinate system.
Data from the GPS Vision are converted into a
format directly acceptable for entry into a GIS.
After the information is analyzed, enginerrs use it
for construction purpose. The GPSVision is an ideal
platform for cost-efficient multimedia collection of
the spatially-referenced digital data that is highly
accurate, current, homogeneous and consistent. The
GPSVision system is also not perfect. The current
GPSVision system covers 20meter range of the each
side of the road. For most application, this is more
than enough. But there are some applications, wider
coverage is required. People may also like to see the
back ground For that purpose, a new study was
conducted by combing the terrestrial GPSVision
image with digital aerial photography. Features
were collected from the GPSVision image and were
also used to rectify aerial images. The aerial image
is then used as background image and also served to
digital the features far away from road. A typical
client can accurately measure and inspect the
infrastructures from images, can simulate the view
as one drives down the road and can create
complete vector map with detailed view from the air
and from the ground.
This paper will discuss the basic issues of integrating
of terrestrial images with aerial images. A brief
description of a mobile mapping system is given,
followed by feature extraction from images and
integration with aerial images. Finally, data set is
presented to demonstrate the applicatiion of
photogrammetric images in roadway construction.
2. GPSVision Data Collection System
The hardware component of the GPSVision mobile
mapping system consists of three major
components, a Trimble dual frequency GPS
receiver, a Litton inertial navigation system and two
progressive scan CCD cameras (one color and one
back/white).
The GPSVision is a very flexible system, many
different types of GPS receivers or cameras are also
used depending on the application requirement The
other important featureof the GPSvision is its
independence with the moving platform, it is
portable and can be mounted on different vehicles.
Fig. 1 shows the GPS receiver, the left camera and
the INS system which are inside the box.
Fig 1 This pod contains GPS, INS and the left
camera of the portable GPSVision system.
A PC-computer provides the overall control,
storage, display and operator interaction during the
data acquisition. It is constructed on a passive back
plane chassis and mounted in a rugged industrial
chassis with a single board CPU. The single board
CPU executes a standard multi-tasking operating
system The back plane also has an INS interface
consisting of a SDCC digital interface, Built-In-Test
(BIT) board, and a timing interface board. In
addition to the boards, the chassis will also contain a
solid state or standard storage device and a boot
device.
The Built-In-Test Diagnostic System provides
hardware status of all sub-systems to the operator
and warns of pending maintenance action or failure
The BIT consists of a digital I/O, a digital to analog
converter and an analog to digital converter board
for monitoring each subsystem
The GPS unit provides the system computer with
GPS timing, satellite data and satellite status
information. The solid state INS provides changes in
direction and speed data. The GPS time is unique
and all collected data are correlated on the GPS
time. Data are stored in a binary format and used in
post-processing software.
The vision system consists of two high resolution
CCD cameras, two digital frame buffers and two
removable hard disks for image storage. The
cameras are progressive scan CCD units with auto
IRIS wide angle lenses. The image capture of stereo
image pairs is user configurable by distance or time
