The Study on Co-calibration Mechanism on Static-movable Camera

Survilllance System

Zhiguo Yan, Yongjie Shi and Hao Ge

The Third Research Institute of Ministry of Public Security, Shanghai, China

yan8375@163.com

Keywords: Pedestrian Detection, Co-calibration, Video Surveillance, SIFT, Face Recognition.

Abstract: Currently, how to automatically realize acquisition, refining and fast retrieval of the target information in

surveillance video has become an urgent demand in public security visual surveillance field. This paper

proposes a new gun-dome camera cooperative system which solves the above problem partly. In the dual-

camera cooperative video-monitoring system, the co-calibration between the master and slave camera is the

key technique. We introduce one kind of automatic co-calibration method in this paper. The experimental

results show the effectiveness and efficiency of this calibration mechanism.

1 INTRODUCTION

In this paper, we propose a new gun-dome camera

cooperative system which adopts master-slave static

panorama-variable view dual cameras cooperative

video-monitoring system. Compared with the above

solutions, it has the following advantages

(Felzenszwalb, 2008):

1) Combining the advantages of the static-

panorama camera and the camera with variable field

of view (FOV), we can get the close shot of specific

objects in the long shot. Meanwhile, we can also

keep the attention to others objects in the distant

scenery. By using this mechanism, we can expand

the breadth and depth of video surveillance system.

FOV of panorama camera is large, and distant scene

can be observed via focusing the moving camera.

Complementary advantages could be obtained by

combining these two cameras. 2) Realize

observation of multiple targets. If only the moving

camera is used for observation of a target, the FOV

of the camera becomes small. When other targets

appear in the FOV, they could not be observed from

the FOV. 3) Facilitate the detection of the target.

Moving target detection method can be used to

detect the target, since the wide angle camera is

static. And if the target motion is not so rapid in the

FOV of the panorama camera, it is easy to trace.

As the object detecion and tracing is concerned ,

the premise lies in the co-calibration mechnisim on

the dual-camera survillance system. In the following

paragraphs, we will discuss it in detail.

2 THE DUAL-CAMERA

CONFIGURATION

Gun-dome camera cooperative system is one kind of

dual-camera monitoring system. There are one wide

angle camera and one Pan Tilt Zoom (PTZ) dome

machine. The wide angle camera is responsible for

the target detection in wide field of view, and PTZ

dome machine (also known as active camera) for

focusing and amplifying and tracking continuously

for the target of attention. Dual-camera cooperative

system function mainly is composed of three parts:

moving object detection in the wide-angle camera,

calibration of the moving camera and the wide-angle

camera, coordinated control of these two cameras.

The proposed gun-dome camera cooperative system

is shown in figure 1. It is key personnel target

detection and recognition application platform

architecture based on gun-dome camera. In figure 1,

there is an overlapping region between the scene

recorded by the gun camera and the scene recorded

by the dome camera, which belonging to the joint

calibration of overlapping scenarios. When

146

Shi Y., Yan Z. and Ge H.

The Study on Co-calibration Mechanism on Static-movable Camera Survilllance System.

DOI: 10.5220/0006020801460149

In Proceedings of the Information Science and Management Engineering III (ISME 2015), pages 146-149

ISBN: 978-989-758-163-2

calibrating, dome camera is in the wide-angle state,

and under this situation, the gun-dome machine has

an overlapping region. The calibration objects

should be placed in the overlapping region in the

joint calibration. The gun camera is responsible for

panoramic monitoring with a wide-angle shot.

Moving target detection is focused on and target

position information is transmitted to the dome

camera under the panoramic field. Meanwhile, in the

scene of dome camera, according to the position

mapping relationship obtained from the gun-dome

camera cooperative calibration, we first transform

the position of the moving target in the gun camera,

and calculate the corresponding coordinate in initial

scene of the dome camera, then we start real-time

PTZ control and realize continuous tracing and

facial image capture of the target of attention.

To realize dual-camera cooperative system need:

Observe and detect targets in the scene with static

wide-angle camera; obtain the position of target and

transmit the position information to the moving

camera; moving camera tracing the target according

to its position and amplify it. The key techniques in

this process is 1) target detection. Wide angle

camera which is static relative to the scene, can

realize pedestrian objective location by motion

detection. Moreover, illumination, swing of

branches and any other factors should be taken into

consideration in actual scene. 2) Calibration of dual

cameras (Cho, 2012). The calibration of gun-dome

camera is to compute the angle which the moving

camera rotates to aim at position of the target in the

static camera. 3) Cooperative control of dual

cameras. According to the state of the target in the

static camera, appropriate cooperative strategy is set

up and the clear image of the target is acquired.

Figure 1: Block diagram of master-slave camera

cooperative system.

As to the dual-camera co-calibration, we should

satisfy the premise that the two camera have the

common vision at the initial stage. After the

execution of the co-calibration, the motion of slave

camera is controlled by the master camera.

3 METHODOLOGY

The calibration of dual cameras is a process of

computing parameters of geometric model of camera

imaging. The calibration methods mainly include

physical model method, look-up table method and

etc (Beriault, 2008; Luo, 2011; Xu, 2015). The

Physical model method calculates the rotation angle

based upon the imaging physical model of the target

in the dual cameras and motion model of cameras.

However, it can only obtain a very accurate rotation

angle theoretically and the practical operation is

much complicated. Compared with physical model

method, Look-up table method is much convenient,

simpler and reliable. In practice, the original

calibration data is still valid when the scene changes

from the learning environment to another.

Figure 2: Process of dual camera calibration.

In the gun-dome cooperative linkage personnel

detection and tracking system, the gun camera has to

transmit the position of pedestrian detected by itself

to the initial scene of dome camera, and then based

on this the dome camera begins to do face detection

and continuous tracking. The realization of the

above functions requires of the mapping relationship

between gun camera and dome camera (Li, 2006).

Namely the imaging position of the object in the gun

camera is mapped into the dome camera, and the

dome camera adjusts the rotation angle in order to

make the object in the centre of image of the dome

camera. Establishing this mapping relation is

implemented through dual camera calibration (Hao,

2010). The calibration of dual camera is referred to

as : under the knowledge of the position of target in

wide angle camera, to find the horizontal rotated

angle

and the vertical rotated angle

, which

make the PTZ camera rotate to aim at target,

[ ( , )] ( , )

L M u v

α β

→

The process can be elaborated with figure 2. First

of all calibrate the internal parameters of cameras;

The Study on Co-calibration Mechanism on Static-movable Camera Survilllance System

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The Study on Co-calibration Mechanism on Static-movable Camera Survilllance System

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Secondly eliminate the distortion of lens of cameras;

Then match the image target in dual camera via the

polar constraint conditions and image features;

Calculate the 3D coordinates of the target under PTZ

camera coordinate system; Finally compute the

rotated angle (

) according to PTZ camera

motion model.

The imaging model of dual cameras is as shown

in Fig. 3. Through the analysis of the physical

process of the dual cameras calibration, there exist a

single mapping

[ y z] ( , )

α β

⇔

between the

current position of the object

[ , , ]

x y z

and absolute

position parameter

( , )

α β

of camera when it is in

the centre of the field of view of image. Thus, if the

relationships between the three dimensional

coordinate of the object

[ , , ]

x y z

and the position

of the camera

( , )

α β

is set up, the calibration of

dual cameras will be realized.

Figure 3: Dual cameras imaging.

The look-up table can be constructed by

supervised learning, in order to acquire the angle

which PTZ camera rotates to aim at the target, and

realize the dual cameras calibration. Detailed steps

are as follows.

1) Choose Region of Interest (ROI) which

needs PTZ camera’s key monitoring in visual

surveillance area of the wide angle camera.

2) Divide ROI of wide angle image into grids

according to appropriate spacing. Then acquire

the pixel coordinates in the grid intersections.

11 1 1 12 1 2 21 2 1 22 2 2

( , ), ( , ), ( , ), ( , ),...,

M x y M x y M x y M x y

3) Adjust the rotation of PTZ camera until the

centre of PTZ camera image coincides with M11.

Then read the current rotation angles in the

horizontal direction and the vertical direction of

PTZ camera

( , )

α β

, and record a group of

data

11 1 1 11

[ ( , )] ( , )

L M x y

α β

4) Repeat the 3) operation for the rest

intersections in ROI of wide angle image and

take notes down all

[ ( , )] ( , )

L M x y

α β

5) Look for the minimum rectangle

encircling non-grid-intersection

S(x, y) in ROI, and calculate the rotation angle of

PTZ camera by means of bilinear interpolation

formula.

11 2 2 12 2 1

2 1 2 1

21 1 2 22 1 1

( , ) [ ( )( )( ) ( )( )( )

( )( )

( )( )( ) ( )( )( )]

L M x x y y L M x x y y

x x y y

L M x x y y L M x x y y

α β

= − − + − − +

− −

− − + − −

(1)

6) Combining data obtained in 3), 4), 5) gives

the look-up table for the PTZ camera rotating

and aiming at arbitrary position of ROI in dome

camera view.

Figure 4: Dual cameras on the same vertical plane.

When calibrating dual cameras in the way of

Look-up Table (Kim, 2009) it is easy to operate with

depth information of the object with regard to the

two cameras changing a little. Therefore, the

installation

positions of the two

camera

s are as

shown in Fig.4 that the lens of each camera

approximat

stay on the same vertical plane.

4 EXPERIMENT

As a comparison, we first execute the calibration

using the classic chess-board method, which

depends on the reference object and is relevant to the

spot circumstance, see Fig. 5.

Figure 5(a): The chessboard for calibration.

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Figure 5(b): The correlation between camera coordinate

and the chessboard coordinate.

As to the above-mentioned cooperative calibration,

we adopted the calibration toolbox on Matlab

platform (Xie, 2012). The classical chessboard is

utilized to get the internal parameter matrixes of the

two component cameras, see Fig. 5(a) The external

matrixes and the rotation and translation relation

between the two cameras is calculated using the 3D

calibration methodology, see Fig. 5(b).

Now, we execute the proposed automatic co-

calibration method, see the Fig. 6.

Figure 6: The interface of the automatic co-calibration

procedure.

In Fig.6, the left image is the scene of master

camera and the right is the slave camera. The green

points painted in the left images is the pre-set

calibration points. These nine points split the whole

into four sections. Those points lie in the four

sections are calibrated by the interpolated methods.

By this mechanism, the procedure can

automatically deal the co-calibration job between the

two cameras. The experiments shows its

effectiveness and efficiency.

ACKNOWLEDGEMENTS

Our research was supported by the Project of

Shanghai Municipal Commission Of Economy and

Information (No.12GA-19), the standard revision

project on public security named “Technical

requirements for interested object detection and

tracing using the collaborative multicamera in

surveillance video system” (No. C14726).

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The Study on Co-calibration Mechanism on Static-movable Camera Survilllance System

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