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THREE LINE SCANER IMAGERY AND ON-STREET PACKED VEHICLE DETECTION 
S. Punvatavungkour ', R.Shibasaki * 
CSIS, The University of Tokyo, CW503, 4-6-1, Komaba, Mekuro-ku, Tokyo, Japan, 153-8505 - (sompoch, 
shiba)(g)skl.iis.u-tokyo.ac.jp 
Commission VI, WG VI/4 
KEY WORDS: Photogrammetry, GIS Acquisition, Object Detection, Segmentation, Pattern Recognition 
ABSTRACT: 
In the study, we proposed new algorithm of stopped vehicle detection using Three Line Scanner Imagery or TLS briefly. A 
framework of our study consists of three stages: Pre-processing 
, Moving/Stopping Vehicle Discrimination and Parking/Signals 
Waiting Vehicle Classification respectively. The Pre-Processing Step is fundamental information preparation such as vehicle-likely 
regions etc from Forward/ Nadir images. In Stopped/ Moving Vehicle Detection algorithms, stopped vehicles are detected by 
grouping vehicle candidates and verifying candidates as detected stopped vehicle as 3d objects using the Stereoscopic measurement 
on forward/nadir TLS images while moving vehicles are extracted by using our new ‘expansion proceed’ method to generate 
moving vehicle candidate and validating candidates as detected vehicles using spatial-temporal techniques on forward/nadir TLS 
images. In our last algorithm, Parking/ Idling Vehicle Classification, on-street parked vehicle is detected by measuring the distance 
from the edge of the road to the side of stopped. Parked vehicle is agreed with this distance thresholding defined by a ground 
observation. The algorithm is typically useful in cities. Finally, the promising results are derived and listed. 
1. INTRODUCTION 
Traffic congestions in urban area worsen quickly. On-street 
vehicle statistics collection is very crucial. A practical and 
effective approach is the vehicle observation by Remote 
Sensing techniques because image from remote sensor 
distributes a top-view and wide-area observation compared with 
ground-based sensors as Video Camera etc and now, remote 
sensing image is higher resolution. Those images are able to 
distribute their merit for object identification. 
  
   
   
Backward-Looking 
Nadir 
Foward-Looking 
Figure 1 Three Line Scanner 
Recently, Three Line Scanner, TLS, novel airborne line- 
imaging sensor, is available. Three Line Scanner imaging 
systems consist of three parallel one-dimensional CCD cameras 
mounted on the imaging plane with a Stabilizer for shaking 
reduction during imaging flight. It obtains seamless ultrahigh- 
resolution images, with three viewing directions (forward, nadir, 
backward direction) simultaneously with RTK-GPS and INS. 
By seamless imaging capability along the road, TLS image is 
355 
very suitable to detect linear feature ground object such as road 
etc. Therefore, in our contribution, by using TLS, on-street 
vehicle monitoring has been developed. 
The merit of TLS is not only distributing 3 dimensional 
imaging but also distributing positioning of Sensor during 
imaging by INS/GPS mounted with sensor. Moreover, due to 
TLS image with centimetre order resolution, the small object 
such as car pillar is identified. Because of tropical liner 
seamless image, it is simple to detect ground linear objects such 
as road etc from the image. Therefore, this image is suitable 
with vehicle detection from TLS imagery 
2. RELATED RESEARCHES 
At the present, there is not much review on vehicle detection 
using aerial image. All of them are categorized into a variety of 
aspects such types of sensors, target vehicle types or types of 
measurement etc. In terms of data, almost all existing methods 
apply frame aerial images. Several authors have presented 
approaches that utilize implicit vehicle models [1] [8]. Many 
successful approaches use explicit models [3] [4]. Although 
both approaches have merits and weak points, the implicit 
model approach, which is based on radiometry, is limited due to 
local radiometric disturbances and uncertainties about the 
accuracy of data training, which varies with illumination, 
viewpoint, and the types of objects in the training data [4]. 
Therefore, the explicit model is possibly more robust than the 
implicit model. 
However, there are neither any approaches that mentioned 
stopped/ moving vehicle detection in one system by using one 
type of data nor parked/ traffic signals waiting vehicle 
discrimination 
Please remind the organization of the paper. Chapter 2 reviews 
existing work of vehicle detection by using aerial image and 
their weak points. The overall structure of our contribution is