KR20160086696A - stereo camera module and calibration method of stereo camera - Google Patents

Abstract

The present invention relates to a calibration method of a stereo camera, which comprises the following steps: obtaining a first image on an object displayed in an image display device through a first camera; obtaining a second image on the object displayed in the image display device through a second camera; and performing calibration through the first and second images.

Description

[0001] The present invention relates to a stereo camera module and a calibration method of a stereo camera,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stereo camera and a method of calibrating a stereo camera that perform calibration through a video display device.

Recently, as interest in autonomous vehicles increases, researches on sensors mounted on autonomous vehicles are actively under way. There are cameras, infrared sensors, radar, GPS, lidar, and gyroscope that are mounted on the autonomous vehicle. Among them, the camera occupies an important position as a sensor that replaces the human eye.

On the other hand, among the cameras provided in the vehicle, the stereo camera can be used for detecting the distance to the obstacle by using the disparity map.

Stereo cameras generally use two cameras with a certain distance left and right. There may be a case where a precise image of a subject is not obtained due to a minute difference between two camera arrangements and a distortion of a lens provided in each of the two cameras. In this case, calibration for the stereo camera is required. Particularly, in a stereo camera mass production system, a method of performing a calibration at a high speed is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of calibrating a stereo camera and a stereo camera that performs calibration through an image display device.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to a first aspect of the present invention, there is provided a method of calibrating a stereo camera, comprising: acquiring a first image of an object displayed on an image display device through a first camera; Acquiring a second image for the object displayed on the image display device, and performing a calibration through the first and second images.

According to another aspect of the present invention, there is provided a method of calibrating a stereo camera, the method comprising the steps of: Displaying a composite image on an image display device, acquiring a first image in the composite image through a first camera including a first polarizing filter, and acquiring, via a second camera including a second polarizing filter, Obtaining a second image from the image, and performing calibration through the first and second images.

The details of other embodiments are included in the detailed description and drawings.

According to an embodiment of the present invention, there is one or more of the following effects.

First, through the calibration, the accurate image of the subject can be obtained.

Second, since the calibration is performed based on the image displayed through the image display device, the calibration can be performed quickly and accurately in the mass production system.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing the appearance of a vehicle having a stereo camera according to an embodiment of the present invention.
Fig. 2 is a view showing the appearance of a stereo camera attached to the vehicle of Fig. 1. Fig.
3A-3B illustrate various examples of an internal block diagram of a stereo camera module according to an embodiment of the present invention.
Figures 4A-4C illustrate various examples of internal block diagrams of the processors of Figures 3A-3B.
Figures 5A-5B are views referenced in the operational description of the processors of Figures 4A-4B.
FIGS. 6A and 6B are views referred to in describing the operation of the stereo camera module of FIGS. 3A to 3B.
Fig. 7 is an example of an internal block diagram of the electronic control unit in the vehicle of Fig. 1. Fig.
8A is a flowchart referred to explain a method of calibrating a stereo camera according to the first embodiment of the present invention.
8B is a flowchart referred to explain a method of calibrating a stereo camera according to the second embodiment of the present invention.
9A to 9B are diagrams for explaining a method of calibrating a stereo camera using an object.
FIGS. 10A to 15B are views referred to explain the calibration method according to the first embodiment of the present invention.
16A to 16B are diagrams referred to describe a calibration method according to a second embodiment of the present invention.
FIGS. 17A through 17D are views referred to explain a calibration method according to a third embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role. In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

Terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The vehicle described herein may be a concept including a car, a motorcycle. Hereinafter, the vehicle will be described mainly with respect to the vehicle.

The vehicle described in the present specification may be a concept including both an internal combustion engine vehicle having an engine as a power source, a hybrid vehicle having an engine and an electric motor as a power source, and an electric vehicle having an electric motor as a power source.

1 is a view showing the appearance of a vehicle having a stereo camera according to an embodiment of the present invention.

Referring to the drawings, a vehicle 200 includes wheels 103FR, 103FL, 103RL, ... rotated by a power source, a handle 150 for adjusting the traveling direction of the vehicle 200, And a stereo camera 195 provided in the mobile terminal 200.

The stereo camera 195 may comprise a plurality of cameras, and the stereo images obtained by the plurality of cameras may be signal processed within the stereo camera module 100 (Fig. 3).

On the other hand, the figure illustrates that the stereo camera 195 includes two cameras.

Fig. 2 is a view showing the appearance of a stereo camera attached to the vehicle of Fig. 1. Fig.

Referring to the drawing, the stereo camera 195 may include a first camera 195a having a first lens 193a, and a second camera 195b having a second lens 193b.

The stereo camera 195 includes a first light shield 192a and a second light shield 192b for shielding light incident on the first lens 193a and the second lens 193b, And a portion 192b.

The stereo camera 195 in the drawing may be a structure detachably attachable to the ceiling or the windshield of the vehicle 200.

A stereo camera module (100 in Fig. 3) having such a stereo camera 195 acquires a stereo image for the front of the vehicle from the stereo camera 195, and performs disparity detection based on the stereo image Performs object detection on at least one stereo image based on the disparity information, and continuously tracks the movement of the object after object detection.

3A-3B illustrate various examples of an internal block diagram of a stereo camera module according to an embodiment of the present invention.

The stereo camera module 100 of FIGS. 3A and 3B performs signal processing based on computer vision based on the stereo image received from the first and second cameras 195a and 195b, Can be generated. Here, the vehicle-related information may include vehicle control information for direct control of the vehicle, or vehicle driving assistance information for a driving guide to the vehicle driver.

3A, the stereo camera module 100 includes a communication unit 120, an interface unit 130, a first memory 140, a processor 170, a power supply unit 190, 1 and a second camera 195a, 195b.

The communication unit 120 can exchange data with the mobile terminal 600 or the server 500 in a wireless manner. In particular, the communication unit 120 can exchange data with a mobile terminal of a vehicle driver wirelessly. As a wireless data communication method, various data communication methods such as Bluetooth, WiFi Direct, WiFi, and APiX are possible.

The communication unit 120 can receive weather information and traffic situation information on the road, for example, TPEG (Transport Protocol Expert Group) information from the mobile terminal 600 or the server 500. Meanwhile, in the stereo camera module 100, it is also possible to transmit real-time traffic information based on the stereo image to the mobile terminal 600 or the server 500.

On the other hand, when the user is boarding the vehicle, the user's mobile terminal 600 and the stereo camera module 100 can perform pairing with each other automatically or by execution of the user's application.

The interface unit 130 can receive the vehicle-related data or transmit the signal processed or generated by the processor 170 to the outside. To this end, the interface unit 130 can perform data communication with a control unit 770, an AVN (Audio Video Navigation) device 400, a sensor unit 760, and the like in the vehicle by a wire communication or a wireless communication method have.

The interface unit 130 can receive map information related to the vehicle driving by data communication with the AVN apparatus 400. [ For example, the AVN device 400 may include navigation and the interface 130 may receive information about the location of the vehicle on the map and the map from the navigation, and may forward it to the processor 170 .

On the other hand, the interface unit 130 can receive the sensor information from the control unit 770 or the sensor unit 760.

Here, the sensor information includes at least one of a slip degree of the vehicle, vehicle direction information, vehicle position information (GPS information), vehicle angle information, vehicle speed information, vehicle acceleration information, vehicle tilt information, vehicle forward / backward information, , Tire information, vehicle lamp information, vehicle interior temperature information, and vehicle interior humidity information.

Such sensor information may include at least one of a wheel speed sensor, a heading sensor, a yaw sensor, a gyro sensor, a position module, a vehicle forward / backward sensor, a wheel sensor, A vehicle speed sensor, a vehicle body inclination sensor, a battery sensor, a fuel sensor, a tire sensor, a steering sensor by steering wheel rotation, a vehicle internal temperature sensor, and a vehicle internal humidity sensor. On the other hand, the position module may include a GPS module for receiving GPS information.

On the other hand, among the sensor information, the vehicle direction information, the vehicle position information, the vehicle angle information, the vehicle speed information, the vehicle tilt information, and the like relating to the vehicle running can be referred to as vehicle running information.

The first memory 140 may store various data for operation of the entire stereo camera module 100, such as a program for processing or controlling the processor 170.

The first memory 140 is electrically connected to the processor 170, and can store basic data for the unit, control data for controlling the operation of the unit, and input / output data. The first memory 140 may be various storage devices such as ROM, RAM, EPROM, flash drive, hard drive, and the like.

An audio output unit (not shown) converts an electric signal from the processor 170 into an audio signal and outputs the audio signal. For this purpose, a speaker or the like may be provided. The audio output unit (not shown) can also output sound corresponding to the operation of the input unit 110, that is, the button.

An audio input unit (not shown) can receive a user's voice. For this purpose, a microphone may be provided. The received voice may be converted to an electrical signal and transmitted to the processor 170.

The processor 170 controls the overall operation of each unit in the stereo camera module 100.

In particular, the processor 170 performs signal processing based on computer vision. Accordingly, the processor 170 obtains a stereo image for the vehicle front from the first and second cameras 195a and 195b, performs a disparity calculation for the vehicle front based on the stereo image, Perform object detection for at least one of the stereo images based on the disparity information, and continue to track the motion of the object after object detection.

Particularly, when detecting an object, the processor 170 may detect lane detection (LD), vehicle detection (VD), pedestrian detection (PD), light detection (Brightspot Detection) Traffic sign recognition (TSR), road surface detection, and the like.

The processor 170 may perform a distance calculation to the detected nearby vehicle, a speed calculation of the detected nearby vehicle, a speed difference calculation with the detected nearby vehicle, and the like.

On the other hand, the processor 170 can generate road surface information of a road under driving based on a stereo image. For example, the processor 170 can distinguish between a dry state, a wet state, a snow state, and an ice state based on differences in luminance data in a stereo image. Specifically, the luminance of the eye state is the highest, and the luminance can be lowered in the order of the dry state, the ice state, and the wet state. The luminance can be divided into the dry state, the wet state, a snow state, and an ice state. As another example, the processor 170 of the stereo camera module 100 may be configured to perform various operations based on the intensity and exposure in the image, such as a dry state, a wet state, a snow state, (ice) state. The processor 170 may output a control signal to the control unit 770 to control the brake driving unit based on the uphill or downhill road surface information and the road surface information before the road.

Meanwhile, the processor 170 can receive weather information, traffic situation information on the road, and TPEG (Transport Protocol Expert Group) information, for example, through the communication unit 120.

Meanwhile, the processor 170 may grasp, in real time, the traffic situation information on the surroundings of the vehicle based on the stereo image in the stereo camera module 100. [

On the other hand, the processor 170 can receive map information and the like from the AVN apparatus 400 via the interface unit 130. [

On the other hand, the processor 170 can receive the sensor information from the control unit 770 or the sensor unit 760 through the interface unit 130. [ Here, the sensor information includes at least one of vehicle sleep information, vehicle direction information, vehicle position information (GPS information), vehicle angle information, vehicle speed information, vehicle acceleration information, vehicle tilt information, vehicle forward / backward information, Tire information, vehicle lamp information, vehicle interior temperature information, and vehicle interior humidity information. The processor 170 may receive control information of each unit provided in the vehicle from the control unit 770 through the interface unit 130. [

On the other hand, the processor 170 can receive road information from the navigation, excluding the area displayed on the stereo image, from among the roads on which the vehicle 200 is traveling, and predict the road state. Specifically, the processor 170 can predict the vehicle front or rear road conditions that are not displayed in the stereo image. Here, the road conditions may include road curves, tunnels, and car athletes.

The processor 170 may be implemented as a digital signal processor (DSP), an application specific integrated circuit (ASIC), a microcontroller, programmable logic devices (PLDs), field programmable gate arrays (FPGAs) And may be mounted on one surface of a predetermined circuit board.

The power supply unit 190 can supply power necessary for the operation of each component under the control of the processor 170. [ Particularly, the power supply unit 190 can receive power from a battery or the like inside the vehicle.

The first and second cameras 195a and 195b may be removably attachable to a ceiling or a wind shield of the vehicle 200. [ The first camera 195a may include a first lens 193a and the second camera 195b may include a second lens 193b.

The first and second cameras 195a and 195b respectively include a first light shield 192a and a second light shield 192b for shielding light incident on the first lens 193a and the second lens 193b, ), And a second optical shield 192b.

Referring to FIG. 3B, the stereo camera module 100 of FIG. 3B further includes an input unit 110 display 180 and an audio output unit 185 in comparison with the stereo camera module 100 of FIG. 3A . Hereinafter, only the description of the input unit 110, the display 180, and the audio output unit 185 will be described.

The input unit 110 may include a plurality of buttons or a touch screen attached to the stereo camera module 100. It is possible to turn on and operate the stereo camera module 100 via a plurality of buttons or a touch screen. In addition, it is also possible to perform various input operations.

The audio output unit 185 outputs the sound to the outside based on the audio signal processed by the processor 170. [ To this end, the audio output unit 185 may include at least one speaker.

Display 180 may display an image related to the operation of the stereo camera module. For this image display, the display 180 may include a cluster or HUD (Head Up Display) on the inside of the vehicle interior. On the other hand, when the display 180 is the HUD, it may include a projection module that projects an image on the windshield of the vehicle 200. [

Figures 4A-4B illustrate various examples of internal block diagrams of the processors of Figures 3A-3B, and Figures 5A-B are views referenced in the operational description of the processors of Figures 4A-4B.

4A is an internal block diagram of the processor 170. The processor 170 in the stereo camera module 100 includes an image preprocessing unit 410, a disparity computing unit 420, An object detecting unit 434, an object tracking unit 440, and an application unit 450.

An image preprocessor 410 receives stereo images from the first and second cameras 195a and 195b and performs preprocessing.

Specifically, the image preprocessing unit 410 may perform a noise reduction, a rectification, a calibration, a color enhancement, a color space conversion, and a color space conversion on a stereo image. CSC, interpolation, camera gain control, and the like. Accordingly, a stereo image that is clearer than the stereo image photographed by the first and second cameras 195a and 195b can be acquired.

The disparity calculator 420 receives the stereo image signal processed by the image preprocessing unit 410, performs stereo matching on the received stereo images, performs stereo matching on the received stereo images, , And obtains a disparty map. That is, it is possible to obtain disparity information about the stereo image with respect to the front of the vehicle.

At this time, the stereo matching may be performed on a pixel-by-pixel basis of the stereo images or on a predetermined block basis. On the other hand, the disparity map may mean a map in which binaural parallax information of stereo images, i.e., left and right images, is numerically expressed.

The segmentation unit 432 may perform segmentation and clustering on at least one of the stereo images based on the disparity information from the disparity calculation unit 420. [

Specifically, the segmentation unit 432 can separate the background and the foreground for at least one of the stereo images based on the disparity information.

For example, an area having dispaly information within a disparity map of a predetermined value or less can be calculated as a background, and the corresponding part can be excluded. Thereby, the foreground can be relatively separated.

As another example, an area in which the dispetity information is equal to or greater than a predetermined value in the disparity map can be calculated with the foreground, and the corresponding part can be extracted. Thereby, the foreground can be separated.

In this manner, by separating the foreground and the background based on the disparity information information extracted based on the stereo image, it becomes possible to shorten the signal processing speed, signal processing amount, and the like at the time of object detection thereafter.

Next, the object detector 434 can detect the object based on the image segment from the segmentation unit 432. [

That is, the object detecting section 434 can detect the object for at least one of the stereo images based on the disparity information information.

Specifically, the object detection unit 434 can detect the object for at least one of the stereo images. For example, an object can be detected from a foreground separated by an image segment.

Next, the object verification unit 436 classifies and verifies the isolated object.

For this purpose, the object identifying unit 436 identifies the objects using a neural network identification method, a SVM (Support Vector Machine) method, a AdaBoost identification method using a Haar-like feature, or a Histograms of Oriented Gradients (HOG) Technique or the like can be used.

On the other hand, the object checking unit 436 can check the object by comparing the objects stored in the first memory 140 with the detected object.

For example, the object checking unit 436 can identify nearby vehicles, lanes, roads, signs, hazardous areas, tunnels, and the like, which are located around the vehicle.

An object tracking unit 440 performs tracking on the identified object. For example, it sequentially identifies an object in the acquired stereo images, calculates a motion or a motion vector of the identified object, and tracks movement of the object based on the calculated motion or motion vector . Accordingly, it is possible to track nearby vehicles, lanes, roads, signs, dangerous areas, tunnels, etc., located in the vicinity of the vehicle.

Next, the application unit 450 can calculate the risk and the like of the vehicle 200 based on various objects located in the vicinity of the vehicle, for example, other vehicles, lanes, roads, signs, and the like. It is also possible to calculate the possibility of a collision with a preceding vehicle, whether the vehicle is slipping or the like.

Then, the application unit 450 can output a message or the like for notifying the user to the user as vehicle driving assistance information, based on the calculated risk, possibility of collision, or slip. Alternatively, a control signal for attitude control or running control of the vehicle 200 may be generated as the vehicle control information.

4B is another example of an internal block diagram of the processor.

Referring to the drawings, the processor 170 of FIG. 4B has the same internal structure as the processor 170 of FIG. 4A, but differs in signal processing order. Only the difference will be described below.

The object detection unit 434 receives the stereo image and can detect the object for at least one of the stereo images. 4A, it is possible to detect the object directly from the stereo image, instead of detecting the object, on the segmented image based on the disparity information.

Next, the object verification unit 436 classifies the detected and separated objects based on the image segment from the segmentation unit 432 and the object detected by the object detection unit 434, (Verify).

For this purpose, the object identifying unit 436 identifies the objects using a neural network identification method, a SVM (Support Vector Machine) method, a AdaBoost identification method using a Haar-like feature, or a Histograms of Oriented Gradients (HOG) Technique or the like can be used.

FIGS. 5A and 5B are views referred to for explaining the operation method of the processor 170 of FIG. 4A based on the stereo images obtained respectively in the first and second frame periods.

First, referring to FIG. 5A, during the first frame period, the first and second cameras 195a and 195b acquire a stereo image.

The disparity calculating unit 420 in the processor 170 receives the stereo images FR1a and FR1b signal-processed by the image preprocessing unit 410 and performs stereo matching on the received stereo images FR1a and FR1b And obtains a disparity map (520).

The disparity map 520 is obtained by leveling the parallax between the stereo images FR1a and FR1b. The higher the disparity level is, the closer the distance is from the vehicle, and the smaller the disparity level is, It is possible to calculate that the distance is long.

On the other hand, when such a disparity map is displayed, it may be displayed so as to have a higher luminance as the disparity level becomes larger, and a lower luminance as the disparity level becomes smaller.

In the figure, first to fourth lanes 528a, 528b, 528c, and 528d have corresponding disparity levels in the disparity map 520, and the construction area 522, the first front vehicle 524 ) And the second front vehicle 526 have corresponding disparity levels, respectively.

The segmentation unit 432, the object detection unit 434 and the object identification unit 436 are configured to determine whether or not a segment, an object detection, and an object detection are performed on at least one of the stereo images FR1a and FR1b based on the disparity map 520. [ Perform object verification.

In the figure, using the disparity map 520, the object detection and confirmation for the second stereo image FR1b is performed.

That is, the first to fourth lanes 538a, 538b, 538c, and 538d, the construction area 532, the first forward vehicle 534, and the second forward vehicle 536 are included in the image 530, And verification may be performed.

Next, referring to FIG. 5B, during the second frame period, the first and second cameras 195a and 195b acquire a stereo image.

The disparity calculating unit 420 in the processor 170 receives the stereo images FR2a and FR2b signal-processed by the image preprocessing unit 410 and performs stereo matching on the received stereo images FR2a and FR2b And obtains a disparity map (540).

In the figure, the first to fourth lanes 548a, 548b, 548c, and 548d have corresponding disparity levels in the disparity map 540, and the construction area 542, the first forward vehicle 544 ) And the second front vehicle 546 have corresponding disparity levels, respectively.

The segmentation unit 432, the object detection unit 434 and the object identification unit 436 are configured to determine whether or not a segment, an object detection, and an object detection are performed on at least one of the stereo images FR2a and FR2b based on the disparity map 540. [ Perform object verification.

In the figure, using the disparity map 540, object detection and confirmation for the second stereo image FR2b is performed.

That is, in the image 550, the first to fourth lanes 558a, 558b, 558c, and 558d, the construction area 552, the first forward vehicle 554, and the second forward vehicle 556, And verification may be performed.

On the other hand, the object tracking unit 440 can compare the FIG. 5A and FIG. 5B and perform tracking on the identified object.

Specifically, the object tracking unit 440 can track movement of the object based on the motion or motion vector of each object identified in FIGS. 5A and 5B. Accordingly, it is possible to perform tracking on the lane, the construction area, the first forward vehicle, the second forward vehicle, and the like, which are located in the vicinity of the vehicle.

6A and 6B are views referred to in the description of the operation of the stereo camera module of FIG.

First, FIG. 6A is a diagram illustrating a vehicle frontal situation photographed by first and second cameras 195a and 195b provided inside a vehicle. In particular, the vehicle front view is indicated by a bird eye view.

Referring to the drawing, a first lane 642a, a second lane 644a, a third lane 646a, and a fourth lane 648a are located from the left to the right, and the first lane 642a and the second The construction area 610a is positioned between the lanes 644a and the first front vehicle 620a is positioned between the second lane 644a and the third lane 646a and the third lane 646a and the fourth It can be seen that the second forward vehicle 630a is disposed between the lane lines 648a.

Next, FIG. 6B illustrates display of the vehicle front situation, which is grasped by the stereo camera module, together with various pieces of information. In particular, the image as shown in FIG. 6B may be displayed on the display 180 or the AVN device 400 provided in the stereo camera module.

6B illustrates that information is displayed on the basis of the images photographed by the first and second cameras 195a and 195b, unlike FIG. 6A.

A first lane 642b, a second lane 644b, a third lane 646b and a fourth lane 648b are located from the left to the right and the first lane 642b and the second The construction area 610b is located between the lanes 644b and the first front vehicle 620b is located between the second lane 644b and the third lane 646b and the third lane 646b and the fourth It can be seen that the second forward vehicle 630b is disposed between the lane 648b.

The stereo camera module 100 performs signal processing on the basis of the stereo image photographed by the first and second cameras 195a and 195b and outputs the processed image to the construction site 610b, the first forward vehicle 620b, An object for the vehicle 630b can be identified. In addition, the first lane 642b, the second lane 644b, the third lane 646b, and the fourth lane 648b can be confirmed.

On the other hand, in the drawing, it is exemplified that each of them is highlighted by a frame to indicate object identification for the construction area 610b, the first forward vehicle 620b, and the second forward vehicle 630b.

On the other hand, the stereo camera module 100 has a construction area 610b, a first front vehicle 620b, a second front vehicle 620b, and a second front vehicle 610b based on a stereo image photographed by the first and second cameras 195a and 195b 630b. ≪ / RTI >

In the figure, calculated first distance information 611b, second distance information 621b, and third distance information 621b corresponding to the construction area 610b, the first forward vehicle 620b, and the second forward vehicle 630b, respectively, Information 631b is displayed.

On the other hand, the stereo camera module 100 can receive sensor information about the vehicle from the control unit 770 or the sensor unit 760. Particularly, it is possible to receive and display the vehicle speed information, the gear information, the yaw rate indicating the speed at which the vehicle's rotational angle (yaw angle) changes, and the angle information of the vehicle.

The figure illustrates that the vehicle speed information 672, the gear information 671 and the yaw rate information 673 are displayed on the vehicle front image upper portion 670. In the vehicle front image lower portion 680, Information 682 is displayed, but various examples are possible. Besides, the width information 683 of the vehicle and the curvature information 681 of the road can be displayed together with the angle information 682 of the vehicle.

Meanwhile, the stereo camera module 100 can receive speed limitation information and the like for the road running on the vehicle through the communication unit 120 or the interface unit 130. [ In the figure, it is exemplified that the speed limitation information 640b is displayed.

The stereo camera module 100 may display various information shown in FIG. 6B through the display 180 or the like, but may store various information without a separate indication. And, by using such information, it can be utilized for various applications.

Fig. 7 is an example of an internal block diagram of the electronic control unit in the vehicle of Fig. 1. Fig.

Referring to the drawings, the vehicle 200 may include an electronic control device 700 for vehicle control. The electronic control apparatus 700 can exchange data with the stereo camera module 100 and the AVN apparatus 400 described above.

The electronic control unit 700 includes an input unit 710, a communication unit 720, a second memory 740, a lamp driving unit 751, a steering driving unit 752, a brake driving unit 753, a power source driving unit 754, A suspension driving unit 756, an air conditioning driving unit 757, a window driving unit 758, an airbag driving unit 759, a sensor unit 760, a control unit 770, a display unit 780, an audio output unit 785, and a power supply unit 790.

The input unit 710 may include a plurality of buttons or a touch screen disposed inside the vehicle 200. Through a plurality of buttons or a touch screen, it is possible to perform various input operations.

The communication unit 720 can exchange data with the mobile terminal 600 or the server 500 in a wireless manner. In particular, the communication unit 720 can exchange data with the mobile terminal of the vehicle driver wirelessly. As a wireless data communication method, various data communication methods such as Bluetooth, WiFi Direct, WiFi, and APiX are possible.

The communication unit 720 can receive weather information and traffic situation information of the road, for example, TPEG (Transport Protocol Expert Group) information from the mobile terminal 600 or the server 500.

On the other hand, when the user aboard the vehicle, the user's mobile terminal 600 and the electronic control device 700 can perform pairing with each other automatically or by execution of the user's application.

The second memory 740 may store various data for operation of the electronic control unit 700, such as a program for processing or controlling the control unit 770.

The second memory 740 is electrically connected to the control unit 770, and can store basic data for the unit, control data for controlling the operation of the unit, and input / output data. The second memory 740 may be various storage devices such as ROM, RAM, EPROM, flash drive, hard drive, and the like.

The lamp driving unit 751 can control the turn-on / turn-off of the lamps disposed inside and outside the vehicle. Also, the intensity, direction, etc. of the light of the lamp can be controlled. For example, it is possible to perform control on a direction indicating lamp, a brake lamp, and the like.

The steering driver 752 may perform electronic control of a steering apparatus (not shown) in the vehicle 200. [ Thus, the traveling direction of the vehicle can be changed.

The brake driver 753 can perform electronic control of a brake apparatus (not shown) in the vehicle 200. [ For example, the speed of the vehicle 200 can be reduced by controlling the operation of the brakes disposed on the wheels. As another example, it is possible to adjust the traveling direction of the vehicle 200 to the left or right by differently operating the brakes respectively disposed on the left wheel and the right wheel.

The power source driving section 754 can perform electronic control of the power source in the vehicle 200. [

For example, when a fossil fuel-based engine (not shown) is a power source, the power source drive unit 754 can perform electronic control of the engine. Thus, the output torque of the engine and the like can be controlled. When the power source driving unit 754 is an engine, the speed of the vehicle can be limited by limiting the engine output torque under the control of the control unit 770. [

As another example, when the electric motor (not shown) is a power source, the power source driving unit 754 can perform control on the motor. Thus, the rotation speed, torque, etc. of the motor can be controlled.

The sunroof driving unit 755 may perform electronic control of a sunroof apparatus (not shown) in the vehicle 200. [ For example, you can control the opening or closing of the sunroof.

The suspension driving unit 756 may perform electronic control of a suspension apparatus (not shown) in the vehicle 200. [ For example, when there is a curvature on the road surface, it is possible to control the suspension device so as to reduce the vibration of the vehicle 200. [

The air conditioning driving unit 757 can perform electronic control on an air conditioner (not shown) in the vehicle 200. For example, when the temperature inside the vehicle is high, the air conditioner can be operated to control the cooling air to be supplied into the vehicle.

The window driving unit 758 may perform electronic control of a window apparatus (not shown) in the vehicle 200. [ For example, it can control the opening or closing of left and right windows on the side of the vehicle.

The airbag driver 759 may perform electronic control of the airbag apparatus in the vehicle 200. [ For example, at risk, the airbag can be controlled to fire.

The sensor unit 760 senses a signal related to the running or the like of the vehicle 100. [ To this end, the sensor unit 760 may include a heading sensor, a yaw sensor, a gyro sensor, a position module, a vehicle forward / backward sensor, a wheel sensor, A vehicle speed sensor, a vehicle body inclination sensor, a battery sensor, a fuel sensor, a tire sensor, a steering sensor by steering wheel rotation, a vehicle interior temperature sensor, and a vehicle interior humidity sensor.

Thereby, the sensor unit 760 outputs the vehicle position information (GPS information), the vehicle angle information, the vehicle speed information, the vehicle acceleration information, the vehicle tilt information, the vehicle forward / backward information, the battery information, Tire information, vehicle lamp information, vehicle internal temperature information, vehicle interior humidity information, and the like.

In addition, the sensor unit 760 may include an accelerator pedal sensor, a pressure sensor, an engine speed sensor, an air flow sensor AFS, an intake air temperature sensor ATS, a water temperature sensor WTS, A position sensor (TPS), a TDC sensor, a crank angle sensor (CAS), and the like.

The control unit 770 can control the overall operation of each unit in the electronic control unit 700. [ Here, the control unit 770 may be an ECU.

It is possible to perform a specific operation by the input by the input unit 710 or to receive the sensed signal from the sensor unit 760 and transmit the sensed signal to the stereo camera module 100 and receive the map information from the AVN apparatus 400 754, 756, 753, 754, 756, respectively.

In addition, the control unit 770 can receive weather information and road traffic situation information, for example, TPEG (Transport Protocol Expert Group) information, from the communication unit 720.

The display unit 780 can display an image related to the operation of the stereo camera module. For this image display, the display unit 780 may include a cluster or an HUD (Head Up Display) on the inside of the vehicle interior. Meanwhile, when the display unit 780 is the HUD, it may include a projection module for projecting an image on the windshield of the vehicle 200. [ On the other hand, the display unit 780 may include a touch screen that can be input.

The audio output unit 785 converts the electric signal from the control unit 770 into an audio signal and outputs the audio signal. For this purpose, a speaker or the like may be provided. The audio output unit 785 can also output a sound corresponding to the operation of the input unit 710, that is, the button.

The power supply unit 790 can supply power necessary for the operation of each component under the control of the control unit 770. Particularly, the power supply unit 790 can receive power from a battery (not shown) inside the vehicle.

8A is a flowchart referred to explain a method of calibrating a stereo camera according to the first embodiment of the present invention.

Referring to FIG. 8A, the first camera 195a obtains a first image of an object displayed on the image display device (S810). That is, the processor 170 acquires the first image of the object displayed on the image display device through the first camera 195a.

The second camera 195b acquires the second image of the object displayed on the image display device (S820). That is, the processor 170 obtains the second image of the object displayed on the image display device through the second camera 195b.

Here, the first image and the second image may be images in which the same objects are displayed in different areas in the image display device. For example, the video display device displays the object in the first area. In this case, the first camera 195a acquires the first image of the object displayed in the first area. Further, the video display device displays the object in the second area. In this case, the second camera 195b obtains the second image of the object displayed in the second area.

Here, the first image and the second image may be images in which the same objects are displayed at different angles in the image display device. For example, the image display device displays the object in a state of being displaced to the first angle with respect to the display portion. In this case, the first camera 195a obtains the first image of the object that is distorted by the first angle. Further, the image display device displays the object in a state of being displaced to the second angle with reference to the display unit. In this case, the second camera 195b obtains the second image of the object that is distorted at the second angle.

On the other hand, the video display device is a device for displaying a predetermined image. For example, the video display device may be a concept including a TV, a computer monitor, a projector, and the like.

On the other hand, the object may be a grid-like screen in which the first color and the second color are alternately filled. For example, an object may be a screen in which white and black are alternately filled, such as a chessboard.

On the other hand, in the first image, a parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the first camera 195a, May be an image of an object.

Alternatively, the first image may be a scaled image of the size of the object, depending on the distance between the first camera 195a and the image display device.

Alternatively, the first image may include a virtual normal line from the first camera 195a to the image display device, and a virtual line extending from the first camera 195a toward the center of the object, with reference to the first camera 195a, May be an image reflecting the angle formed by the angle.

On the other hand, in the second image, the parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the second camera 195b, and the image of the object displayed on the image display device .

Alternatively, the second image may be a scaled image of the size of the object, depending on the distance between the second camera 195b and the image display device.

Alternatively, the second image may include a virtual normal line from the second camera 195b to the image display device, and a virtual line extending from the second camera 195b toward the center of the object, with reference to the second camera 195b, May be an image reflecting the angle formed by the angle.

Thereafter, the processor 170 determines whether the first and second images have been acquired a predetermined number of times (S830).

Here, the reference number means the first and second image acquisition times required to perform the calibration of the first and second cameras 195a and 195b. The reference number may be a predetermined value by an experiment.

If the first and second images are acquired a predetermined number of times, the processor 170 may perform the calibration through the obtained first and second images (S840).

For example, the processor 170 may compare the first and second images to generate a calibration correction value. Thereafter, the processor 170 may generate a calibration table reflecting the generated calibration correction values. Thereafter, the processor 170 may apply the calibration table when a stereo image is acquired through the first and second cameras 195a, 195b.

If it is determined in step S830 that the first and second images have not been acquired for the reference number of times, steps S810 and S820 are repeated.

8B is a flowchart referred to explain a method of calibrating a stereo camera according to the second embodiment of the present invention.

The video display device displays the composite image (S860). Here, the composite image is an image in which the first image and the second image are combined. The first image may be an image in which a parallax according to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the first camera 195a. The second image may be an image in which the parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the second camera 195b.

With the composite image displayed on the image display device, the first camera 195a acquires the first image and the second camera 195b acquires the second image (S870). The first camera 195a may include a first polarizing filter, and the second camera 195b may include a second polarizing filter.

The first camera 195a can separate and acquire only the first image in the composite image based on the first light filtered by the one polarization filter. That is, the processor 170 can acquire the first image separated by the first polarizing filter through the first camera 195a.

The second camera 195b can separate and acquire only the second image in the composite image based on the second light filtered by the second polarization filter. That is, the processor 170 may acquire the second image separated by the second polarizing filter through the second camera 195b.

Here, the first image and the second image may be images in which the same objects are displayed in different areas in the image display device. For example, the video display device displays the object in the first area. In this case, the first camera 195a acquires the first image of the object displayed in the first area. Further, the video display device displays the object in the second area. In this case, the second camera 195b obtains the second image of the object displayed in the second area.

Here, the first image and the second image may be images in which the same objects are displayed at different angles in the image display device. For example, the image display device displays the object in a state of being displaced to the first angle with respect to the display portion. In this case, the first camera 195a obtains the first image of the object that is distorted by the first angle. Further, the image display device displays the object in a state of being displaced to the second angle with reference to the display unit. In this case, the second camera 195b obtains the second image of the object that is distorted at the second angle.

On the other hand, the video display device is a device for displaying a predetermined image. For example, the video display device may be a concept including a TV, a computer monitor, a projector, and the like.

On the other hand, the object may be a grid-like screen in which the first color and the second color are alternately filled. For example, an object may be a screen in which white and black are alternately filled, such as a chessboard.

On the other hand, in the first image, a parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the first camera 195a, May be an image of an object.

Alternatively, the first image may be a scaled image of the size of the object, depending on the distance between the first camera 195a and the image display device.

Alternatively, the first image may include a virtual normal line from the first camera 195a to the image display device, and a virtual line extending from the first camera 195a toward the center of the object, with reference to the first camera 195a, May be an image reflecting the angle formed by the angle.

On the other hand, in the second image, the parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the second camera 195b, and the image of the object displayed on the image display device .

Alternatively, the second image may be a scaled image of the size of the object, depending on the distance between the second camera 195b and the image display device.

Alternatively, the second image may include a virtual normal line from the second camera 195b to the image display device, and a virtual line extending from the second camera 195b toward the center of the object, with reference to the second camera 195b, May be an image reflecting the angle formed by the angle.

Thereafter, the processor 170 determines whether the first and second images have been acquired a predetermined number of times (S880).

Here, the reference number means the first and second image acquisition times required to perform the calibration of the first and second cameras 195a and 195b. The reference number may be a predetermined value by an experiment.

If the first and second images are acquired a predetermined number of times, the processor 170 may perform the calibration through the obtained first and second images (S890).

For example, the processor 170 may compare the first and second images to generate a calibration correction value. Thereafter, the processor 170 may generate a calibration table reflecting the generated calibration correction values. Thereafter, the processor 170 may apply the calibration table when a stereo image is acquired through the first and second cameras 195a, 195b.

If it is determined in step S880 that the first and second images are not acquired a predetermined number of times, steps S860 and S870 are repeated.

9A and 9B are diagrams for explaining a method of calibrating a stereo camera using an object according to an embodiment of the present invention.

9A and 9B, a stereo camera 195, that is, a first camera 195a and a second camera 195b, photographs an object 930. [ Here, the first camera 195a may be called a left camera or a left camera. The second camera 195b may be called a right eye camera or a right camera.

As shown in FIG. 9A, the first camera 195a has a first angle of view 915. FIG. And the second camera 195b has a second angle of view 925. [ The first angle of view 915 and the second angle of view 925 may be the same.

On the other hand, the first camera 195a and the second camera 195b are separated by a distance d1. The first camera 195a and the object 930 are separated by d2. Also, the second camera 195a and the object 930 are separated by d2.

Here, the object 930 is biased toward the first camera 195a.

Figs. 9A and 9B show the left-eye image 940L from the first camera 195a and the right-eye image from the second camera 195b, which are photographed under the condition of Fig. 9A (a) (940R). 9A illustrates a left-right arrangement of a left-eye image 940L and a right-eye image 940R, and FIG. 9C illustrates a top-down arrangement of a left-eye image 940L and a right-eye image 940R.

9A and 9B, the object 942L in the left eye image 940L and the object 942R in the right eye image 940R have no positional difference in the Y axis direction (As shown in FIG. 9 (b)), and there is a position difference d3 in the X-axis direction (as shown in FIG. 9 (c)). That is, the object 942R in the right eye image 940R may be located further left than the object 942L in the left eye image 940L. Since the first camera 195a and the second camera 195b are disposed apart from each other in the left and right directions, there is no difference in position in the Y axis direction in the obtained images 940L and 940R, A difference occurs.

The processor 170 calculates the difference d3 of the positions of the objects 942L and 942R in the X-axis direction in the images 940L and 940R, i.e., the disparity, The distance d2 between the first camera 195a and the second camera 195b can be calculated using the distance d1 between the first camera 195a and the second camera 195b.

On the other hand, in manufacturing the stereo camera module 100, an error may occur due to physical arrangement between the cameras 195a and 195b and distortion of lenses provided in both cameras depending on the manufacturing process.

In this case, due to the error of the horizontal interval or the vertical interval of the left eye camera 195a and the right eye camera 195b, a serious distance error may occur when distance measurement is performed based on the photographed stereo image. Alternatively, when the parallax is calculated after the detection of the same object in the image, the calculation amount increases due to the change of the position of the object in the image, so that the calculation speed may increase.

Therefore, a calibration process for correcting such an error is required.

In the present invention, the stereo camera is calibrated in consideration of errors in horizontal or vertical intervals of the left and right eye cameras 195a and 195b, lens distortion, and the like.

For example, when the object 942L in the left eye image 940L and the object 942R in the right eye image 940R make a difference on the Y-axis, the processor 170 performs the calibration so that the difference is eliminated.

For example, when the difference between the object 942L in the left eye image 940L and the object 942R in the right eye image 940R occurs on the X axis by more than the reference distance, Calibration is performed to eliminate the difference.

For example, if the object 942L in the left eye image 940L and the object 942R in the right eye image 940R are distorted by a straight line, then the processor 170 may perform a calibration such that the curve is displayed in a straight line .

FIG. 9B illustrates an operation of acquiring an object 930 in a layout different from FIG. 9A through the first camera 195a and the second camera 195b to perform the calibration.

9A, the object 930 is biased toward the second camera 195b side, as shown in FIG. 9B (a).

The object 952L in the left eye image 950L and the object 952R in the right eye image 950R are moved in the Y axis direction by a difference in position (B) of FIG. 9B), but there is a position difference d4 in the X-axis direction (the example shown in FIG. 9B (c)). That is, the object 952L in the left eye image 950L may be located further to the right than the object 952R in the right eye image 950R. Since the first camera 195a and the second camera 195b are disposed apart from each other in the left and right directions, there is no difference in position in the Y axis direction in the obtained images 950L and 950R, A difference occurs.

FIGS. 10A to 15B are views referred to explain the calibration method according to the first embodiment of the present invention.

On the other hand, the method of acquiring and calibrating an object image according to the first embodiment applies the contents described with reference to Figs. 9A to 9B.

10A illustrates an operation for acquiring a first image through a first camera 195a.

The first camera 195a and the second camera 195b are separated by a distance d1. The first camera 195a and the image display device 1010 are separated by d2a. That is, the first camera 195a and the object 1020a displayed on the image display device 1010 are separated by d2a.

The first camera 195a acquires a first image of the object 1020a displayed on the image display device 1010. [

On the other hand, the object 1020a displayed in the first image may be an image that is distorted at a predetermined angle in the first direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the left side of the object 1020a, which is displayed in the first image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. Also, the right side of the object 1020a, which is displayed in the first image, faces the direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed on the first image may be a three-dimensional shape in which the left side is close to the right side and the right side is far away. Since the first image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that the three-axis direction can be calibrated in the spatial coordinates of X, Y, and Z.

On the other hand, the object 1020a may be a grid-like screen in which the first color and the second color are alternately filled. For example, the object 1020a may be a screen in which white and black are alternately filled, such as a chessboard.

On the other hand, in the first image, a parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the first camera 195a, It may be a virtual image of an object. Since the first camera 195a and the second camera 195b are spaced apart by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The image has a positional difference in the X-axis direction. The first image may be an image that reflects the difference in position in the X-axis direction in advance.

The first image may be a scaled virtual image according to the distance between the first camera 195a and the image display device 1010. [ The image obtained by photographing the actual object 1020b separated by d2 from the first camera 195a through the first camera 195a and the image obtained by capturing the actual image 1020b separated by d2a from the first camera 195a The image obtained by photographing the object 1020a displayed on the display 1010 may be the same. In this case, the object 1020a displayed in the first image may be one in which the size of the actual object 1020b is scaled and displayed in consideration of d2 and d2a.

On the other hand, the first image may be an image in which parallax and scaling are simultaneously reflected. That is, the first image is a virtual image in which the distance d1 between the first camera 195a and the second camera 195b and the distance d2a between the first camera 195a and the image display device are reflected have. Here, the time difference reflection means that the distance d1 between the first camera 195a and the second camera 195b is reflected. The scaling reflects the distance d2a between the first camera 195a and the image display device 1010 and the distance d2 between the first camera 195a and the actual object 1020b. It means the size is scaled. That is, the first camera 195a shoots a virtual object 1020a scaled down by a distance ratio of d2 and d2a, instead of shooting the actual object 1020b by d2.

When the calibration is performed using the object 1020a displayed on the image display device 1010 by the time difference or the scaling is reflected and the screen switching can be performed faster and the calibration is performed using the actual object 1020b The object image can be acquired more quickly and quick calibration can be performed.

FIG. 10B illustrates an operation for acquiring a second image through a second camera 195b.

The first camera 195a and the second camera 195b are separated by a distance d1. The second camera 195b and the image display device 1010 are separated by d2a. That is, the second camera 195b and the object 1020a displayed on the image display device 1010 are separated by d2a.

The second camera 195b acquires a second image of the object 1020a displayed on the image display device 1010. [

On the other hand, the object 1020a displayed on the second image may be an image in a state in which the object 1020a is rotated at a predetermined angle in the first direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the left side of the object 1020a displayed on the second image faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. Also, the right side of the object 1020a, which is displayed in the second image, faces the direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed on the second image may be a three-dimensional shape in which the left side is close to the right side and the right side is far away. Since the second image is displayed in this three-dimensional shape, the perspective can be displayed, and calibration can be performed in three axial directions in the spatial coordinates of X, Y, Z.

On the other hand, the object 1020a may be a grid-like screen in which the first color and the second color are alternately filled. For example, the object 1020a may be a screen in which white and black are alternately filled, such as a chessboard.

On the other hand, in the second image, a parallax corresponding to the distance between the first camera 195a and the second camera 195b is reflected on the basis of the second camera 195a, It may be a virtual image of an object. Since the first camera 195a and the second camera 195b are spaced apart by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The image has a positional difference in the X-axis direction. The second image may be an image that reflects the difference in position in the X-axis direction in advance. For example, the object 1020a displayed on the image display device 1010 in FIG. 10B may be further left by a predetermined distance from the object 1020a displayed on the image display device 1010 in FIG. 10A. That is, the object 1020a displayed on the image display device 1010 in FIG. 10A may be disposed on the right side by a predetermined distance from the object 1020a displayed in the image display device 1010 in FIG. 10B.

Meanwhile, the second image may be a scaled virtual image according to the distance between the second camera 195a and the image display device 1010. The image obtained by photographing the actual object 1020b separated by d2 from the second camera 195a through the second camera 195a and the image obtained from the second camera 195a by the distance d2a from the image display device The image obtained by photographing the object 1020a displayed on the display 1010 may be the same. At this time, the object 1020a displayed in the second image may be one in which the size of the actual object 1020b is scaled and displayed in consideration of d2 and d2a.

On the other hand, the second image may be an image in which parallax and scaling are simultaneously reflected. That is, the second image is a virtual image in which the distance d1 between the first camera 195a and the second camera 195b and the distance d2a between the first camera 195a and the image display device are reflected have. Here, the time difference reflection means that the distance d1 between the first camera 195a and the second camera 195b is reflected. The scaling reflects the distance d2a between the second camera 195a and the image display device 1010 and the distance d2 between the second camera 195a and the actual object 1020b. It means the size is scaled. That is, the second camera 195a shoots a virtual object 1020a scaled down by a distance ratio d2 and d2a, instead of shooting the actual object 1020b in a state of being separated by d2.

When the calibration is performed using the object 1020a displayed on the image display device 1010 by the time difference or the scaling is reflected and the screen switching can be performed faster and the calibration is performed using the actual object 1020b The object image can be acquired more quickly and quick calibration can be performed.

10C and 10D illustrate the left eye image 1030L photographed through the first camera 195a and the right eye image 1030R photographed through the second camera 195b under the conditions of FIGS. 10A and 10B.

FIG. 10C is a diagram in which a left eye image 1030L and a right eye image 1030R are arranged horizontally, and FIG. 10D is a diagram in which a left eye image 1030L and a right eye image 1030R are arranged vertically.

The object 1032L in the left eye image 1030L and the object 1032R in the right eye image 1030R have no positional difference on the Y axis as shown in Fig. If there is a difference in position on the Y axis of each of the objects 1032L and 1032R, calibration is required. Processor 170 may perform calibration such that each object 1032L, 1032R has no positional difference on the Y-axis.

As shown in Fig. 10D, the position of the object 1032L in the left eye image 1030L and the object 1032R in the right eye image 1030R differ from each other by d5 on the X axis. If the difference in position generated in each of the objects 1032L and 1032R is larger or smaller than d5, calibration is required. Processor 170 may perform a calibration such that each object 1032L, 1032R has a positional difference by d5 on the X-axis.

11A to 11D are different from FIGS. 10A to 10D in that there is a difference between the objects 1020a in the first and second images displayed on the image display device 1010, and the rest are the same. The difference will be mainly described below.

FIG. 11A illustrates an operation for acquiring a first image through a first camera 195a.

The object 1020a, which is displayed in the first image, may be an image that is distorted at a predetermined angle in the second direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the right side of the object 1020a, shown in the first image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. The left side of the object 1020a displayed in the first image is directed in a direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the first image may be a three-dimensional shape in which the right side is close to the left side and the left side is far away. Since the first image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that the three-axis direction can be calibrated in the spatial coordinates of X, Y, and Z.

FIG. 11B illustrates an operation for acquiring a second image through a second camera 195b.

The object 1020a, which is displayed in the second image, may be an image with a predetermined angle in the second direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the right side of the object 1020a, shown in the first image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. The left side of the object 1020a displayed in the first image is directed in a direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the first image may be a three-dimensional shape in which the right side is close to the left side and the left side is far away. Since the first image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that the three-axis direction can be calibrated in the spatial coordinates of X, Y, and Z.

Since the first camera 195a and the second camera 195b are spaced apart from each other by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The acquired image has a positional difference in the X-axis direction. The second image may be an image that reflects the difference in position in the X-axis direction in advance. For example, the object 1020a displayed on the image display device 1010 in FIG. 11B may be located further leftward by a predetermined distance from the object 1020a displayed on the image display device 1010 in FIG. 11A. That is, the object 1020a displayed on the image display device 1010 in FIG. 11A may be disposed on the right side by a predetermined distance from the object 1020a displayed in the image display device 1010 in FIG. 11B.

Figs. 11C and 11D illustrate a left-eye image 1040L photographed through the first camera 195a and a right-eye image 1040R photographed through the second camera 195b under the conditions of Figs. 11A and 11B.

FIG. 11C is a diagram in which a left-eye image 1040L and a right-eye image 1040R are arranged horizontally and FIG. 11D is a diagram in which a left-eye image 1040L and a right-eye image 1040R are arranged vertically.

As shown in Fig. 11C, the object 1042L in the left eye image 1040L and the object 1042R in the right eye image 1040R have no positional difference on the Y axis. If there is a difference in position on the Y axis of each of the objects 1042L and 1042R, calibration is required. Processor 170 may perform a calibration such that each object 1042L, 1042R has no positional difference on the Y-axis.

As shown in Fig. 11D, the object 1042L in the left eye image 1040L and the object 1042R in the right eye image 1040R differ in position by d6 on the X-axis. If the difference in position occurring in each of the objects 1042L and 1042R is greater than or less than d6, calibration is required. Processor 170 may perform a calibration such that each object 1042L, 1042R has a positional difference by d6 on the X-axis.

12A to 12D are different from FIGS. 10A to 10D in that there is a difference in the objects 1020a in the first and second images displayed on the image display device 1010, and the rest are the same. The difference will be mainly described below.

12A illustrates an operation for acquiring a first image through a first camera 195a.

The object 1020a displayed in the first image may be an image that is distorted at a predetermined angle in the third direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the top of the object 1020a, shown in the first image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. In addition, the lower side of the object 1020a displayed in the first image is directed in the direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the first image may be a three-dimensional shape in which the upper side is closer and the lower side is distant. Since the first image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that the three-axis direction can be calibrated in the spatial coordinates of X, Y, and Z.

FIG. 12B illustrates an operation for acquiring a second image through a second camera 195b.

The object 1020a displayed on the second image may be an image that is distorted with a predetermined angle in the third direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the top of the object 1020a, shown in the second image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. In addition, the lower side of the object 1020a displayed in the second image faces in a direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the second image may be a three-dimensional shape in which the upper side is closer and the lower side is distant. Since the second image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that calibration can be performed in three axial directions in the spatial coordinates of X, Y, and Z.

Since the first camera 195a and the second camera 195b are spaced apart from each other by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The acquired image has a positional difference in the X-axis direction. For example, the object 1020a displayed on the image display device 1010 in FIG. 12B may be an image displayed on the image display device (not shown in FIG. 12A) 1010 may be disposed a predetermined distance from the object 1020a displayed on the left side. That is, the object 1020a displayed on the image display device 1010 in FIG. 12A may be disposed on the right side by a predetermined distance from the object 1020a displayed in the image display device 1010 in FIG. 12B.

Figs. 12C and 12D illustrate a left-eye image 1050L photographed through the first camera 195a and a right-eye image 1050R photographed through the second camera 195b under the conditions of Figs. 12A and 12B.

12C is a view in which the left eye image 1050L and the right eye image 1050R are arranged horizontally and FIG. 12D is a view in which the left eye image 1050L and the right eye image 1050R are arranged vertically.

As shown in Fig. 12C, the object 1052L in the left eye image 1050L and the object 1052R in the right eye image 1050R have no positional difference on the Y axis. If there is a difference in position on the Y axis of each of the objects 1052L and 1052R, calibration is required. The processor 170 may perform a calibration such that each object 1052L, 1052R has no positional difference on the Y-axis.

As shown in FIG. 12D, the object 1052L in the left-eye image 1050L and the object 1052R in the right-eye image 1050R differ in position by d7 on the X-axis. If the difference in position generated in each of the objects 1052L and 1052R is larger or smaller than d7, calibration is required. The processor 170 may perform a calibration such that each object 1052L, 1052R has a positional difference by d7 on the X-axis.

13A to 13D, there is a difference between the objects 1020a in the first and second images displayed on the image display device 1010, and the rest are the same, as compared with Figs. 10A to 10D. The difference will be mainly described below.

13A illustrates an operation for acquiring a first image through a first camera 195a.

The object 1020a, which is displayed in the first image, may be an image that is distorted at a predetermined angle in the fourth direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the lower side of the object 1020a, shown in the first image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. Also, the top of the object 1020a displayed in the first image is directed in a direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the first image may be a three-dimensional shape in which the lower side is closer and the upper side is distant. Since the first image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that the three-axis direction can be calibrated in the spatial coordinates of X, Y, and Z.

FIG. 13B illustrates an operation for acquiring a second image through a second camera 195b.

The object 1020a, which is displayed in the second image, may be an image that is distorted at a predetermined angle in the fourth direction. At this time, the predetermined angle is preferably 10 to 30 degrees. For example, the lower side of the object 1020a, which is displayed in the second image, faces the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. In addition, the top of the object 1020a displayed in the second image is directed in a direction opposite to the direction in which the image display device 1010 faces the first and second cameras 195a and 195b. At this time, the object 1020a displayed in the second image may be a three-dimensional shape in which the lower side is closer and the upper side is distant. Since the second image is displayed in this three-dimensional shape, the perspective can be expressed, and there is an effect that calibration can be performed in three axial directions in the spatial coordinates of X, Y, and Z.

Since the first camera 195a and the second camera 195b are spaced apart from each other by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The acquired image has a positional difference in the X-axis direction. The second image may be an image that reflects the difference in position in the X-axis direction in advance.

On the other hand, in FIG. 13B, the object 1020a displayed on the image display device 1010 may be disposed on the left side by a predetermined distance from the object 1020a displayed on the image display device 1010 in FIG. That is, the object 1020a displayed on the image display device 1010 in FIG. 13A may be disposed on the right side by a predetermined distance from the object 1020a displayed in the image display device 1010 in FIG.

13C and 13D illustrate the left eye image 1060L photographed through the first camera 195a and the right eye image 1060R photographed through the second camera 195b under the condition of FIGS. 13A and 13B.

Fig. 13C is a view in which the left eye image 1060L and the right eye image 1060R are arranged horizontally, and Fig. 13D is a view in which the left eye image 1060L and the right eye image 1060R are arranged vertically.

As shown in Fig. 13C, the object 1062L in the left eye image 1060L and the object 1062R in the right eye image 1060R have no positional difference on the Y axis. If there is a difference in position on the Y axis of each of the objects 1062L and 1062R, calibration is required. The processor 170 may perform a calibration such that each object 1062L, 1062R has no positional difference on the Y-axis.

As shown in Fig. 13D, the object 1062L in the left eye image 1060L and the object 1062R in the right eye image 1060R are displaced by d8 on the X axis. If the difference in position occurring in each of the objects 1062L and 1062R is greater than or less than d8, calibration is required. The processor 170 may perform a calibration such that each object 1062L, 1062R has a positional difference by d8 on the X-axis.

FIGS. 14A and 14B illustrate the obtained left and right images when distortion occurs in the lens provided in the first camera 195a.

As shown in FIG. 14A, when distortion occurs in the lens provided in the first camera 195a, distortion may occur in the object 1412L in the left eye image 1410L acquired through the first camera 195a . Specifically, a portion of the object 1412L that should be displayed in a straight line in the horizontal direction can be represented by a curve 1414L.

On the other hand, no distortion occurs in the object 1412R in the right eye image 1410R acquired through the second camera 195b having the lens with no distortion. The portion 1414R in the right eye image 1410R corresponding to the distorted portion 1414L in the left eye image 1410L is displayed in a straight line in the horizontal direction.

The processor 170 can perform the calibration so that the distortion portion 1414L disappears for the distortion portion 1414L of the left eye image 1410L. Specifically, the processor 170 may perform calibration such that the curve 1414L is straight.

On the other hand, as shown in FIG. 14B, when distortion occurs in the lens provided in the first camera 195a, distortion may occur in the object in the left eye image 1420L obtained through the first camera 195a. Specifically, a part of the object 1422L to be displayed as a straight line in the longitudinal direction can be represented by a curve 1424L.

On the other hand, no distortion occurs in the object 1422R in the right eye image 1420R acquired through the second camera 195b having the lens with no distortion. The portion 1424R in the right eye image 1420R corresponding to the distortion portion 1424L in the left eye image 1420L is displayed in a straight line in the vertical direction.

The processor 170 can perform the calibration so that the distortion portion 1424L is eliminated for the distortion portion 1424L of the left eye image 1420L. Specifically, the processor 170 may perform calibration such that the curve 1424L is straight.

15A-15B are diagrams that are referenced to describe first and second images according to an embodiment of the invention.

 Referring to FIG. 15A, the first camera 195a photographs a first image displayed on the image display device 1010. FIG. Here, the first image has a virtual normal 1530 directed from the first camera 195a to the image display device, and a second normal camera 1530 extending from the first camera 195a toward the center of the object May be an image reflecting the angle alpha formed by the virtual line 1540.

As described above, the object 1520a in the first image may reflect the parallax or scaling in the real object 1520b. In this case, the first image may be an angle formed by a virtual normal line 1530 from the first camera 195a to the image display device and an imaginary line 1540 extending from the first camera 195a toward the center of the object alpha), so that the parallax or scaling can be reflected.

On the other hand, the first camera 195a may acquire a plurality of first images to perform a sophisticated calibration. At this time, the image display device 1010 can display a plurality of first images in which objects 1520a are displayed in different areas. In this case, the first image may be an angle formed by a virtual normal line 1530 from the first camera 195a to the image display device and an imaginary line 1540 extending from the first camera 195a toward the center of the object alpha).

Referring to FIG. 15B, the second camera 195b acquires a second image displayed on the image display device 1010. FIG. Here, the second image is a virtual normal 1570 directed from the second camera 195b toward the image display device, and a second normal camera 1530 extending from the second camera 195b toward the center of the object, with reference to the second camera 195b May be an image reflecting the angle beta formed by the imaginary line 1580. [

As described above, the object 1520a in the second image may be reflected in the real object 1520b, such as parallax or scaling. In this case, the second image is an angle formed by an imaginary normal line 1570 from the first camera 195a to the image display device and an imaginary line 1580 extending from the first camera 195a toward the center of the object beta), so that the parallax or scaling can be reflected.

On the other hand, the second camera 195b may acquire a plurality of second images to perform a sophisticated calibration. At this time, the image display device 1010 can display a plurality of second images in which the objects 1520a are displayed in different areas. In this case, the second image is an angle formed by a virtual normal line 1570 from the second camera 195b toward the image display device and an imaginary line 1580 extending from the second camera 195b toward the center of the object beta).

16A to 16B are diagrams referred to describe a calibration method according to a second embodiment of the present invention.

On the other hand, the calibration method according to the second embodiment applies mutatis mutandis to the description with reference to Figs. 9A to 15B.

As shown in Fig. 16A, the image display device 1010 displays a composite image 1620a. Here, the composite image 1620a is an image in which the first image and the second image described above are synthesized.

Here, the first image is reflected on the parallax according to the distance between the first camera 195a and the second camera 195b on the basis of the first camera 195a, and is displayed on the image display device It may be a virtual image of an object. Since the first camera 195a and the second camera 195b are spaced apart by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The image has a positional difference in the X-axis direction. The first image may be an image that reflects the difference in position in the X-axis direction in advance.

Alternatively, the first image may be a scaled virtual image of the size of the object, depending on the distance between the first camera 195a and the image display device 1010. [ The image obtained by photographing the actual object 1020b separated by d2 from the first camera 195a through the first camera 195a and the image obtained by capturing the actual image 1020b separated by d2a from the first camera 195a The image obtained by photographing the object 1020a displayed on the display 1010 may be the same. In this case, the object 1020a displayed in the first image may be one in which the size of the actual object 1020b is scaled and displayed in consideration of d2 and d2a.

Alternatively, the first image may be an image in which parallax and scaling are simultaneously reflected. That is, the first image is a virtual image in which the distance d1 between the first camera 195a and the second camera 195b and the distance d2a between the first camera 195a and the image display device are reflected have. Here, the time difference reflection means that the distance d1 between the first camera 195a and the second camera 195b is reflected. The scaling reflects the distance d2a between the first camera 195a and the image display device 1010 and the distance d2 between the first camera 195a and the actual object 1020b. It means the size is scaled.

Here, the parallax according to the distance between the first camera 195a and the second camera 195b is reflected in the second image on the basis of the second camera 195a, and is displayed on the image display device It may be a virtual image of an object. Since the first camera 195a and the second camera 195b are spaced apart by d1, when the same object is photographed, the image obtained through the first camera 195a and the image obtained through the second camera 195b The image has a positional difference in the X-axis direction. The second image may be an image that reflects the difference in position in the X-axis direction in advance.

Alternatively, the second image may be a scaled virtual image of the size of the object, depending on the distance between the second camera 195a and the image display device 1010. [ The image obtained by photographing the actual object 1020b separated by d2 from the second camera 195a through the second camera 195a and the image obtained from the second camera 195a by the distance d2a from the image display device The image obtained by photographing the object 1020a displayed on the display 1010 may be the same. At this time, the object 1020a displayed in the second image may be one in which the size of the actual object 1020b is scaled and displayed in consideration of d2 and d2a.

Alternatively, the second image may be an image in which parallax and scaling are simultaneously reflected. That is, the second image is a virtual image in which the distance d1 between the first camera 195a and the second camera 195b and the distance d2a between the first camera 195a and the image display device are reflected have. Here, the time difference reflection means that the distance d1 between the first camera 195a and the second camera 195b is reflected. The scaling reflects the distance d2a between the second camera 195a and the image display device 1010 and the distance d2 between the second camera 195a and the actual object 1020b. It means the size is scaled.

With the composite image displayed on the image display device, the first camera 195a acquires the first image and the second camera 195b acquires the second image. The first camera 195a may include a first polarizing filter 1630a and the second camera 195b may include a second polarizing filter 1630b.

The first camera 195a can separate and acquire only the first image in the composite image based on the first light filtered by the one polarization filter 1630a. That is, the processor 170 may acquire the first image separated by the first polarizing filter 1630a through the first camera 195a.

The second camera 195b can separate and acquire only the second image from the composite image based on the second light filtered by the second polarization filter 1630b. That is, the processor 170 may acquire the second image separated by the second polarizing filter 1630b through the second camera 195b.

FIG. 16B illustrates a left eye image and a right eye image obtained according to the second embodiment of the present invention.

Figs. 16B and 16C illustrate a left-eye image 1630L photographed through the first camera 195a and a right-eye image 1630R photographed through the second camera 195b under the condition of Fig. 16A.

FIG. 16B is a diagram in which a left-eye image 1630L and a right-eye image 1630R are arranged horizontally, and FIG. 16C is a diagram in which a left-eye image 1630L and a right-eye image 1630R are arranged vertically.

As shown in Fig. 16B, the object 1632L in the left eye image 1630L and the object 1632R in the right eye image 1630R have no positional difference on the Y axis. If there is a difference in position on the Y axis of each of the objects 1632L and 1632R, calibration is required. The processor 170 may perform the calibration so that the respective objects 1632L and 1632R have no positional difference on the Y-axis.

As shown in Fig. 16B, the object 1632L in the left eye image 1630L and the object 1632R in the right eye image 1630R differ in position by d9 on the X-axis. If the difference in position occurring in each of the objects 1632L and 1632R is greater than or less than d9, calibration is required. Processor 170 may perform calibration such that each object 1632L, 1632R has a positional difference by d9 on the X-axis.

FIGS. 17A through 17D are views referred to explain a calibration method according to a third embodiment of the present invention.

In the calibration method according to the first and second embodiments of the present invention, the processor 170 compares the left eye image and the right eye image with each other and performs calibration.

In the calibration method according to the third embodiment of the present invention, the processor 170 may perform calibration by comparing the reference image with the acquired image. The calibration according to the third embodiment can be applied to both the left eye image and the right eye image.

Meanwhile, information about the reference image 1710 may be stored in the first memory 140. Here, the reference image 1710 may store a reference image for a left eye image and a reference image for a right eye image, respectively. In the following description, the left eye image is used as a reference, but the right eye image can be processed in the same manner as the left eye image.

When the left eye images 1720, 1730, 1740 and 1750 are obtained through the first camera 195a, the processor 170 compares the reference image 1710 with the left eye images 1720, 1730, 1740 and 1750, Can be performed.

As shown in FIG. 17A, when a position difference d10 occurs on the Y-axis, the processor 170 may perform the calibration such that the difference d10 is eliminated. That is, the processor 170 may perform calibration to make the acquired left eye image 1720 the same as the reference image 1710.

On the other hand, as shown in FIG. 17B, when a difference d11 occurs in the position on the X axis, the processor 170 may perform the calibration so that the difference d11 is eliminated. That is, the processor 170 may perform calibration to make the acquired left eye image 1730 the same as the reference image 1710. [

17C, when distortion occurs in the lens provided in the first camera 195a, distortion occurs in the object 1742 in the left eye image 1740 acquired through the first camera 195a . Specifically, a portion of the object 1742 that should be displayed as a straight line in the horizontal direction may be represented by a curve 1744. [

The processor 170 may perform the calibration such that for the distorted portion 1744 of the left eye image 1742, the distorted portion 1744 disappears. Specifically, the processor 170 may perform a calibration such that the curve 1744 is straight.

17D, when distortion occurs in the lens provided in the first camera 195a, distortion occurs in the object in the left eye image 1750 acquired through the first camera 195a (1752) . Specifically, a portion of the object 1752 that should be displayed in a straight line in the longitudinal direction can be represented by a curve 1754. [

The processor 170 may perform a calibration such that for the distorted portion 1754 of the left eye image 1750, the distorted portion 1754 disappears. Specifically, the processor 170 may perform a calibration such that the curve 1754 is straight.

The present invention described above can be embodied as computer-readable codes on a medium on which a program is recorded. The computer readable medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of the computer readable medium include a hard disk drive (HDD), a solid state disk (SSD), a silicon disk drive (SDD), a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, , And may also be implemented in the form of a carrier wave (e.g., transmission over the Internet). In addition, the computer may include a processor 170 or a controller 770. Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

100: Stereo camera
170: Processor
195a: First camera
195b:

Claims (13)

Acquiring a first image of the object displayed on the image display device through the first camera;
Acquiring a second image of the object displayed on the display device through a second camera; And
And performing a calibration through the first and second images. The method according to claim 1,
Wherein the object is a grid-shaped screen in which the first color and the second color are alternately filled. The method according to claim 1,
The first image may include a parallax corresponding to a distance between the first camera and the second camera on the basis of the first camera so that the stereoscopic image, which is an image of the object displayed on the image display device, / RTI > The method according to claim 1,
Wherein the second image has a parallax according to a distance between the first camera and the second camera based on the second camera, and the parallax of the stereo camera, which is an image of the object displayed on the video display device, / RTI > The method according to claim 1,
Wherein the first image comprises:
Wherein the size of the object is a scaled image according to a distance between the first camera and the image display device. The method according to claim 1,
Wherein the first image comprises:
A calibration of a stereo camera which is an image in which an angle formed by an imaginary normal line from the first camera to the image display device and an imaginary line extending from the first camera toward the center of the object is reflected on the basis of the first camera, Way. The method according to claim 1,
Wherein the second image comprises:
Wherein the size of the object is a scaled image according to a distance between the second camera and the image display device. The method according to claim 1,
Wherein the second image comprises:
Which is an image reflecting an angle formed by a virtual normal line from the second camera to the video display device and an imaginary line extending from the second camera toward the center of the object on the basis of the second camera, Way. A first image of an object reflecting the parallax according to the distance between the first camera and the second camera on the basis of the first camera and a second image of the object reflecting the parallax on the basis of the second camera, Displaying a synthesized composite image on an image display device;
Separating and acquiring the first image from the composite image through a first polarization filter included in the first camera and separating the second image from the composite image through a second polarization filter included in the second camera ; And
And performing a calibration through the first and second images. 10. The method of claim 9,
Wherein the acquiring comprises:
Obtaining the first image in which the parallax is reflected based on the first light filtered by the first polarized light filter based on the first light; And
And obtaining the second image in which the parallax is reflected on the basis of the second light filtered by the second polarized light filter based on the second light filtered by the second polarized light filter. 10. The method of claim 1 or 9,
Wherein the performing comprises:
Wherein the calibration is performed based on a difference between coordinates of an object displayed in the first image and coordinates of an object displayed in the second image. 10. The method of claim 1 or 9,
Wherein the performing comprises:
Generating a calibration correction value based on the first and second images, and generating a calibration table reflecting the calibration correction value; And
And applying the calibration table to the stereo image if a stereo image is acquired through the first and second cameras. A first camera for acquiring a first image of an object displayed on an image display device;
A second camera for acquiring a second image of the object displayed on the image display device; And
And a processor for performing calibration through the first and second images.

Images