KR101492419B1 - System for processing reflection image enhanced degree of precision by correcting error of reflection image - Google Patents

Abstract

The present invention relates to a system using an image processing method with improved image preciseness by correcting an error. Provided is a system using an image processing method with improved image preciseness by correcting an error, wherein a control unit compares data of recorded building with numerical map data saved in a memory if a worker operates an input device to enable a pair of observation cameras to simultaneously record a specific portion of a corresponding building while being moved nearby the specific building by driving a vehicle in order to automatically correct an error in the numerical map data if correction is needed in location information of the corresponding building. The present invention relates to a numerical map system which includes a global positioning system (GPS) unit (10) disposed in a vehicle (1) to output coordinate data of the vehicle (1); an azimuth measurer (20) disposed in the vehicle (1) to measure the azimuth of the vehicle (1); a base (15) fixed and installed to the vehicle (1) by an impact absorption member (15a) disposed on a lower surface; a pedestal (30) disposed at the base (15); and a pair of observation cameras (60).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an image processing method and an image processing method,

The present invention relates to a system to which an image processing method is applied which improves the accuracy of a video image by error correction among image processing fields. More particularly, the present invention relates to a system for automatically measuring the position of a newly- The present invention relates to a system to which a video image processing method with improved accuracy of a video image is applied.

In general, digital maps are digital data of aerial photographs, and they are widely used in GIS such as navigation for automobiles along with GPS.

On the other hand, when the position information of a digital map is to be corrected, such as a new building such as a building or a bridge is built according to landfill or reclamation, the position of the building is measured and then the information of the measured building is input to the digital map The data of the digital map should be corrected.

However, in order to modify the digital map, the process is very cumbersome, and a system that can easily modify the digital map has become necessary.

As a conventional technique for solving some of these problems, Korean Patent Registration No. 10-0888721 (Mar. 23, 2009) discloses a "digital map system capable of correcting errors of the terrain changes."

However, there is a disadvantage that it is difficult to adjust the height of the registered patent according to some improved prior art.

Korea Patent Registration No. 10-0888721 (Mar. 23, 2009) "Digital Map System that can correct the error of terrain change"

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems in the prior art, and it is an object of the present invention to provide an image processing apparatus, The control unit compares the data of the photographed building with the digital map data stored in the memory so as to automatically correct errors of the digital map data when the location information of the building needs to be corrected The present invention has been made to provide a system to which an image processing method with improved accuracy of a video image with an error correction is applied.

Means for Achieving the Object According to the Present Invention The present invention provides a vehicle comprising: a GPS unit (10) provided in a vehicle (1) for outputting coordinate data of a vehicle (1); An azimuth angle measuring device (20) provided on the vehicle (1) for measuring an azimuth angle of the vehicle (1); A base 15 fixed to the vehicle 1 through a buffer member 15a provided on a lower surface thereof; A support base 30 provided on the base 15; A digital map system including a pair of observation cameras (60), comprising: a pivot table (40) rotatably mounted on the pontoons (30); A horizontal bar 50 hingedly coupled to the pivot 40 and spaced apart from the pair of observation cameras 60; First and second tilt measurement sensors (70, 80) provided on the pivot table (40) and the horizontal table (50) for measuring the tilt of the pivot table (40) and the horizontal table (50); A first driving device 90 connected to the pivotal table 40 to rotate the pivotal table 40; A second driving device 100 connected to the horizontal bar 50 to rotate the horizontal bar 50; A third driving device 110 connected to the observation camera 60 to rotate the observation camera 60 horizontally; An angle measuring sensor (120) connected to the observation camera (60) and measuring an angle of a direction of the observation camera (60); A memory 131 on which the digital map data is mounted is provided and connected to the first and second tilt measurement sensors 70 and 80, the angle measurement sensor 120, the GPS unit 10 and the azimuth measurement device 20 A control unit (130) for controlling the first to third driving devices (90, 100, 110); An input device 140 connected to the control unit 130; Further comprising a monitor (150) connected to the observation camera (60) and displaying an image photographed by the observation camera (60), wherein the control unit (130) And controls the first and second driving apparatuses 100 according to the output signals of the first and second tilt measurement sensors 70 and 80 so as to control the tilting table 40 and the horizontal table And a control unit for controlling the third driving unit 110 according to a control signal input through the input unit 140 to control the direction of the observation camera 60 A relative position calculation unit 134 connected to the angle measurement sensor 120 for calculating an angle of the observation camera 60 and calculating a relative position of an object photographed by the camera, , The GPS unit 10, the azimuth measurement device 20 and the relative position calculation unit 134, And a comparison determining unit 135 for comparing the digital map data with the digital map data stored in the memory 131 and correcting the digital map data. 600); On one side or both sides of the frame 600, a horizontal gear HR having a racetrack shape is fixedly arranged in the longitudinal direction; The horizontal gear HR has a pair of first and second moving blocks 620 and 630 coupled to the horizontal gear HR and having a pinion gear engaged therewith. The pinion gears installed in the first and second moving blocks 620 and 630 are configured to be rotationally driven by the first and second air motors 640 and 650, respectively; On the surface of the first and second moving blocks 620 and 630, an inclined guide member 660 having a bearing shape is installed; The inclined guide member 660 is configured to be guided up and down by inserting a height adjuster 670 having a trapezoidal shape. The height adjuster 670 is constrained to each other by a link 680; A seat 690 is fixed to an upper end of the height adjuster 670; A buffer member 15a is fixed to the upper surface of the seating table 690; A base 15 is fixed to the upper end of the buffer member 15a; And a support base 30 is fixed to the upper surface of the base 15 to provide a system to which an image processing method with improved accuracy of a video image is applied.

According to the present invention, it is possible to automatically correct a location information error of a digital map by automatically measuring the position of a newly constructed building or the like in accordance with the change of the terrain, thereby obtaining the accuracy of information.

FIG. 1 is a side sectional view showing a system to which an image processing method according to an embodiment of the present invention is applied,
FIG. 2 is a rear view showing a system to which an image processing method according to the present invention is applied,
FIG. 3 is a plan view showing a system to which a method of processing a video image, which improves the accuracy of a video image by error correction according to the present invention,
FIG. 4 is a block diagram of a system to which an image processing method according to an embodiment of the present invention is applied,
FIG. 5 is a reference view showing an operation of a system to which a method of processing a video image, which improves the accuracy of a video image by error correction according to the present invention,
6 is an exemplary diagram illustrating a further embodiment according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The present invention uses the above-mentioned prior-art patent No. 0888721 as it is. Therefore, all of the features of the apparatus described below are those described in Patent No. 0888721. [

However, the present invention is characterized in that the improved part of the configuration disclosed in the above-mentioned Japanese Patent No. 0888721 is capable of adjusting the angle of the support as a whole.

Therefore, the device structure, characteristics, and operation relationship described below will be incorporated by reference in the above-mentioned Japanese Patent Application No. 0888721, and the structure related to the main features of the present invention will be described in detail at the rear end.

1 to 4, the present invention comprises a GPS unit 10 provided in the vehicle 1 and outputting coordinate data of the vehicle 1; An azimuth angle measuring device (20) provided on the vehicle (1) for measuring an azimuth angle of the vehicle (1); A base 15 fixed to the vehicle 1 through a buffer member 15a provided on a lower surface thereof; A support base 30 provided on the base 15; A pivot 40 mounted on the support 30 so as to be vertically rotatable; A horizontal stand 50 hinged to the pivot stand 40 so as to intersect with the pivot stand 40; A pair of observation cameras (60) rotatably mounted on the horizontal table (50) so as to be spaced apart from each other; First and second tilt measurement sensors (70, 80) provided on the pivot table (40) and the horizontal table (50) for measuring the tilt of the pivot table (40) and the horizontal table (50); A first driving device 90 connected to the pivotal table 40 to rotate the pivotal table 40; A second driving device 100 connected to the horizontal bar 50 to rotate the horizontal bar 50; A third driving device 110 connected to the observation camera 60 to rotate the observation camera 60 horizontally; An angle measuring sensor (120) connected to the observation camera (60) and measuring an angle of a direction of the observation camera (60); The first and second tilt measurement sensors 70 and 80 and the angle measurement sensor 120 are connected to the GPS unit 10 and the azimuth measurement device 20. The first to third tilt measurement sensors 70 and 80, A control unit (130) for controlling the control unit (130); An input device 140 connected to the control unit 130; And a monitor 150 connected to the observation camera 60 and displaying an image photographed by the observation camera 60.

The GPS unit 10 is provided integrally with the vehicle 1 and outputs coordinate data of the vehicle 1 to indirectly measure and output the current coordinate data of the observation camera 60. [

The azimuth measurement device 20 is provided integrally with the vehicle 1 and measures the azimuth of the vehicle 1 so that the azimuth of the azimuth measurement camera 60 can be indirectly measured. At this time, the azimuth means an angle in the direction toward the front of the vehicle 1 with respect to the north direction.

The base 15 is made of a rectangular metal plate and is configured to support the load of the support 30. The cushioning member 15a on the lower surface of the base 15 is made of a rubber material and disposed so as to support the lower corner portion of the base 15. The cushioning member 15a has both ends connected to the roof surface of the vehicle 1, So as to absorb the impact generated when the vehicle 1 is driven so as to prevent the first to third driving devices 90, 100, 110 including the observation camera 60 from being damaged by the impact.

The support base 30 is formed in a vertically long rod shape and is fixed to the upper surface of the base 15.

The swivel base 40 has a hinge shaft 41 provided horizontally at its base end so as to be pivotally coupled to the middle portion of the support base 30 and extend to the rear side of the support base 30.

An intermediate portion of the horizontal base 50 is rotatably coupled to a support shaft 42 provided at a distal end of the rotary base 40 and connected to the rotary base 40 in a T- So that both ends thereof are rotated in the vertical direction.

The observation camera 60 is configured to automatically adjust the focus and is provided with a telephoto lens. The lower part of the observation camera 60 is provided with a vertical rotation axis 61, Respectively.

The first and second tilt measurement sensors 70 and 80 use a general tilt sensor such that the first tilt measurement sensor 70 is provided on the pivot 40 and the second tilt measurement sensor 80, Are provided respectively in the horizontal table 50 and function to measure the tilt angle of the pivot table 40 and the horizontal table 50 with respect to the horizontal plane and output the measured tilt data.

The first driving device 90 includes a drive shaft 91 rotated by a drive motor not shown and the drive shaft 91 is fixed to the support base 30 by a hinge shaft 41 So that the driving shaft can be rotated by the driving motor to adjust the inclination of the rotating table 40.

The second driving device 100 includes a driving shaft 101 that is rotated by a driving motor not shown in the figure. When the driving shaft 101 is fixed to the horizontal table 50, And is configured to be able to adjust the tilt of the horizontal table 50 by rotating the drive shaft with the driving motor.

The third driving unit 110 includes a driving shaft 111 rotated by a driving motor not shown and the driving shaft 111 is fixed to the horizontal shaft 50 by a rotation axis 61 of the observation camera 60 So that the direction of the observation camera 60 can be adjusted by rotating the rotation shaft 61 with the driving motor to rotate the observation camera 60 in the left and right direction. At this time, the third driving device 110 is connected to each of the observation cameras 60 so that the directions of the observation cameras 60 can be separately adjusted.

The angle measurement sensor 120 is coupled to the rotation axis 61 of each observation camera 60 and detects the angle of each observation camera 60, And the angles? 1 and? 2 in the direction in which the light source 60 is directed.

The control unit 130 includes a memory 131 on which the digital map data is mounted, a horizontal control unit 132 for controlling the pivot table 40 and the horizontal table 50 to maintain a horizontal state, A direction adjusting unit 133 that adjusts the direction of the observation camera 60 and calculates the angle of the observation camera 60 connected to the angle measurement sensor 120 to calculate a relative position of the building 2 photographed by the camera The relative position calculator 134 receives the data output from the GPS unit 10, the azimuth measurement device 20 and the relative position calculator 134 and compares and analyzes the data with the digital map data stored in the memory 131, And a comparison determination unit 135 for correcting the map data.

The horizontal control unit 132 receives the output signals of the first and second tilt measurement sensors 70 and 80 to monitor the inclination of the pivot 40 and the horizontal pivot 50, When the horizontal table 50 is inclined with respect to the horizontal, the first and second driving devices 90 and 100 are controlled to control the rotary table 40 and the horizontal table 50 to be in a horizontal state.

When the operator inputs a control signal through the input device 140, the direction control unit 133 controls the third driving device 110 according to a control signal to control the direction of the observation camera 60 Function.

At this time, the operator separately controls the directions of the respective observation cameras 60 to control each of the observation cameras 60 to photograph the same part of the building 2.

The relative position calculation unit 134 is connected to the angle measurement sensor 120 connected to each observation camera 60 and receives and calculates the angle data output from the angle measurement sensor 120, 5, when the angle of the observation camera 60 is adjusted so as to photograph the same point of the building 2, the relative position calculation unit 134 calculates the relative position of the observation camera 60 from the angle measurement sensor 120 The angular data θ1 and θ2 that are output are received and the relative positions of the building 2 photographed by the observation cameras 60 at the same time and the respective observation cameras 60 are measured and output using the triangulation method .

The comparison determining unit 135 compares the coordinate data of the vehicle 1 output from the GPS unit 10 with the azimuth data output from the azimuth measuring apparatus 20 and the relative position output from the relative position calculating unit 134 A function of calculating the position data and measuring the coordinates of the building 2 simultaneously photographed by the pair of observation cameras 60 based on the position of the vehicle 1 and the function of measuring the coordinates of the measured building 2 and the digital map It compares and analyzes the data and corrects errors of the digital map data.

5, the operator uses the input device 140 to measure the coordinates of the building 2 of the comparison determination unit 135, and the observation camera 60 The comparison judging unit 135 compares the GPS unit 10 and the azimuth angle measuring device 60 with each other so that the two observation cameras 60 simultaneously photograph the right corners of the object 2, And receives coordinate data and azimuth data of the vehicle 1 outputted from the vehicle 20.

Since the support base 30, the pivot 40 and the horizontal base 50 are fixed to the vehicle 1, the coordinate data and the azimuth data of the vehicle 1 are computed and stored in the horizontal base 50 The coordinates and the azimuth angle of each of the observation cameras 60 can be known.

The comparator 135 compares the coordinate and azimuth data of the observation camera 60 measured in this manner and the relative positions of the observation camera 60 and the right side corner of the building 2 output from the relative position calculator 134 The coordinates of the right corner of the building 2 can be measured by calculating the position data.

By repeating this process and measuring the coordinates of each corner of the building 2, it is also possible to measure the entire width and area of the building 2.

The comparing and determining unit 135 compares the coordinate data of the measured building 2 with the numerical map data by using the above described procedure. And check whether there is an abnormality in the digital map data. That is, the numerical map data is searched, and the data of the building 2 is not input, or the coordinates of the building 2 on the digital map data and the coordinates of the building 2 measured through the above- It is determined that there is an error in the digital map data, and correction data such as inputting the coordinate data of the building 2 into the digital map or re-entering the coordinates of the building 2 is automatically performed.

At this time, the operator can additionally input other data such as the name of the building 2 by using the input device 140.

The input device 140 includes a joystick for adjusting the angle of the camera and a keyboard for inputting other data.

The monitor 150 is configured to simultaneously display an image photographed by each observation camera 60 and digital map data using a screen division method. Therefore, the operator can visually check the image displayed on the monitor 150, and control so that each observation camera 60 accurately shoots the same point of the building 2. [

Accordingly, when the operator turns on the control unit 130 after stopping the vehicle 1 around the building 2 to be observed, the horizontal control unit 132 controls the first and second tilt measurement sensors 70, The operator can control the first and second driving devices 90 and 100 to keep the rotary table 40 and the horizontal table 50 in a horizontal state according to the signal of the input device 140 Each observation camera 60 can observe the observation camera 60 so that the observation camera 60 accurately captures a specific point that is easy to be visually recognized such as the same point of the building 2, that is, the same window, door, The control unit 130 has a function of measuring the coordinates of the building 2 and a function of measuring the coordinates of the measured building 2 ) Is compared with the numerical map data and the numerical map data is corrected.

In the case of this embodiment, correction of the error of the numerical map data for the building 2 is exemplified, but it is also possible to use it for correcting the error of the data of the numerical map about the road or other civil structure, if necessary.

A numerical map system capable of correcting a self-error of a terrain change configured as described above is a system in which an observer camera 60 adjusts the observation camera 60 to photograph one point of the building 2 and then inputs a control command to the building 2 It is very easy to use and correct because it corrects errors of numerical map data automatically by checking the numerical map data.

In addition, since the operator can adjust the direction of the observation camera 60 while visually checking the image captured by the observation camera 60 and displayed on the monitor 150, the reliability is very high.

The cushioning member 15a is provided under the base 15 to absorb the impact generated when the vehicle 1 is moved so that the first to third driving operations including the observation camera 60, There is an advantage that damage to the devices 90, 100, and 110 can be prevented.

When the operator turns on the control unit 130 after stopping the vehicle 1 around the building 2 to be observed, the horizontal control unit 132 controls the first and second tilt measurement sensors 70, The first and second driving devices 90 and 100 are controlled in accordance with the signals of the first and second driving devices 80 and 80 so that the turning platform 40 and the horizontal platform 50 are maintained in a horizontal state, The horizontal unit 50 is maintained in a horizontal state at all times, so that accurate measurement can be performed.

With such a configuration as a basic premise, the additional embodiment according to the present invention further includes a height adjustment unit 600 for performing height adjustment quickly and accurately, as shown in FIG.

At this time, the height adjusting unit 600 includes a frame 610.

The frame 610 is fixed to the upper surface of the vehicle 1 as a basic support frame for height adjustment guidance.

On one side of the frame 610, a horizontal gear HR is installed in the longitudinal direction of the frame 610.

In this case, the horizontal gear HR may be a railing gear and may be installed on one side of the frame 610 as well as on both sides if necessary.

The horizontal gear HR is provided with a pair of first and second movable blocks 620 and 630 which are movable along the horizontal gear HR.

Although not shown in detail, the first and second moving blocks 620 and 630 are assembled on one side of the frame 610, that is, the side on which the horizontal gear HR is installed, so that the first and second moving blocks 620 and 630 are slidable in the left and right directions.

For this, protrusions 612 protruding in an inverted trapezoid shape as shown in the figure are protruded in the frame 610, and grooves 622 corresponding to the shapes are formed on corresponding surfaces of the first and second movable blocks 620 and 630 And a pinion gear (not shown) that is gear-engaged with the horizontal gear HR is rotatably provided.

First and second air motors 640 and 650 are installed below the first and second moving blocks 620 and 630, respectively. The motor shaft (not shown) of the first and second air motors 640 and 650 is provided with the above- The gear is fixed.

Accordingly, when the first and second air motors 640 and 650 are driven, the first and second moving blocks 620 and 630 can move along the horizontal gear HR, respectively.

In addition, the inclined guide members 660 are fixed to the surfaces of the first and second movable blocks 620 and 630 so as to be symmetrical to each other.

The inclined guide member 660 is a kind of bearing that guides the up and down movement of the height adjuster 670 in contact with the height adjuster 670 having a substantially trapezoidal shape.

The raised ends of the height adjuster 670 are connected to each other by a link 680.

Therefore, since the height adjuster 670 maintains a fixed shape, the height adjuster 670 can be raised and lowered naturally according to the moving direction of the first and second moving blocks 620 and 630.

That is, when the first and second moving blocks 620 and 630 move in directions away from each other, the height adjuster 670 is engaged with the first and second moving blocks 620 and 630, In contrast, when the first and second moving blocks 620 and 630 are brought close to each other, the height adjuster 670 is pushed up.

This is a phenomenon that occurs when the first and second air motors 640 and 650 described above are rotated in opposite directions while being rotated at different speeds. Since the height adjuster 670 is tied by the link 680, This is a normal operation.

A cushioning pad 690 is fixed to an upper end of the height adjuster 670 and a cushioning member 15a is fixed to an upper surface of the cushioning pad 690. A base 15 are fixed to the upper surface of the base 15, and a support table 30 is fixed to the upper surface of the base 15. [

Accordingly, when the height adjustment is promptly required, the height adjuster 670 can be raised or lowered through rotation control of the first and second air motors 640 and 650, so that the height can be adjusted within a short time .

10: GPS unit 20: azimuth measuring device
30: Support 40:
50: Horizontal band 60: Observation camera

Claims (1)

A GPS unit (10) provided in the vehicle (1) for outputting coordinate data of the vehicle (1); An azimuth angle measuring device (20) provided on the vehicle (1) for measuring an azimuth angle of the vehicle (1); A base 15 fixed to the vehicle 1 through a buffer member 15a provided on a lower surface thereof; A support base 30 provided on the base 15; A digital map system including a pair of observation cameras (60), comprising: a pivot table (40) rotatably mounted on the pontoons (30); A horizontal bar 50 hingedly coupled to the pivot 40 and spaced apart from the pair of observation cameras 60; First and second tilt measurement sensors (70, 80) provided on the pivot table (40) and the horizontal table (50) for measuring the tilt of the pivot table (40) and the horizontal table (50); A first driving device 90 connected to the pivotal table 40 to rotate the pivotal table 40; A second driving device 100 connected to the horizontal bar 50 to rotate the horizontal bar 50; A third driving device 110 connected to the observation camera 60 to rotate the observation camera 60 horizontally; An angle measuring sensor (120) connected to the observation camera (60) and measuring an angle of a direction of the observation camera (60); A memory 131 on which the digital map data is mounted is provided and connected to the first and second tilt measurement sensors 70 and 80, the angle measurement sensor 120, the GPS unit 10 and the azimuth measurement device 20 A control unit (130) for controlling the first to third driving devices (90, 100, 110); An input device 140 connected to the control unit 130; Further comprising a monitor (150) connected to the observation camera (60) and displaying an image photographed by the observation camera (60), wherein the control unit (130) And controls the first and second driving apparatuses 100 according to the output signals of the first and second tilt measurement sensors 70 and 80 so as to control the tilting table 40 and the horizontal table And a control unit for controlling the third driving unit 110 according to a control signal input through the input unit 140 to control the direction of the observation camera 60 A relative position calculation unit 134 connected to the angle measurement sensor 120 for calculating an angle of the observation camera 60 and calculating a relative position of an object photographed by the camera, , The GPS unit 10, the azimuth measurement device 20 and the relative position calculation unit 134, And a comparison determination unit 135 for comparing and analyzing the digital map data stored in the memory 131 and the digital map data,
A frame 600 having a height in the form of a desk is further fixed on the upper surface of the vehicle 1; On one side or both sides of the frame 600, a horizontal gear HR having a racetrack shape is fixedly arranged in the longitudinal direction; The horizontal gear HR has a pair of first and second moving blocks 620 and 630 coupled to the horizontal gear HR and having a pinion gear engaged therewith. The pinion gears installed in the first and second moving blocks 620 and 630 are configured to be rotationally driven by the first and second air motors 640 and 650, respectively; On the surface of the first and second moving blocks 620 and 630, an inclined guide member 660 having a bearing shape is installed; The inclined guide member 660 is configured to be guided up and down by inserting a height adjuster 670 having a trapezoidal shape. The height adjuster 670 is constrained to each other by a link 680; A seat 690 is fixed to an upper end of the height adjuster 670; A buffer member 15a is fixed to the upper surface of the seating table 690; A base 15 is fixed to the upper end of the buffer member 15a; And a support table (30) is fixed on the upper surface of the base (15).

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