KR101048873B1 - Drawing process system for the numerical map by gps - Google Patents

Abstract

PURPOSE: A drawing process system for the numerical map by GPS is provided to display location information of reference point within an image in aero survey. CONSTITUTION: A drawing process system for the numerical map by GPS process the photo image manufacture for a first fuse using the aerial photo photography and the synthesis of the recorded aerial photo. The ground control points interlinked to a ground object are acquired from the photo image for the first fuse through the horizontal control point location survey and milestone buried location survey. A control module(270) receives the location information which is transmitted from a transmitting module(253).

Description

Drawing process system for the numerical map by GPS by setting resolution of numerical map image

The present invention relates to a GPS-based image processing system by setting the resolution of the digital map image.

As is well known, digital mapping can be produced by using a surveying instrument on the ground, a method of combining ground survey data with photographs or images taken using an aircraft or satellite, etc. There are ways to modify the topographic map and make it. The production method using aerial photographs or satellite imagery is more economical than the production method using surveying equipment on the ground, so it is widely used for mapping large areas.

Numerical map production using aerial photographs proceeds with the production of the first drawing photographic image by photographing aerial photographs and synthesizing the photographed aerial photographs, and reading from the primary drawing photographic images through plane reference point surveying and surface laying surveying. After acquiring the ground reference points to connect with this clear ground object, finally, digital drawing data is produced and output through photographic reference point survey, analysis drawing and drawing drawing.

In order to check the accuracy of the digital drawing data, the field survey is conducted with the printed drawing diagram to determine the width and location of the roads and facilities, and return to the office to edit the location to correct the errors in the drawing process. In the process of drawing production and editing, the final correction and editing are made in accordance with the map schematic to complete the digital map production.

As described above, the drawing operation of the drawing image as the background is essential for the production of the digital map, and the reference point as the reference is absolutely essential for the drawing operation.

By the way, the reference point check, as described above, the buried surface measurement and the designation of the ground reference point had to be made essentially at the site. That is, the worker visits the site where the surface is buried for drawing, checks the location, and displays the location on the first drawing picture image as a reference for the GPS location.

However, this drawing process has to be done repeatedly inside and outside the work, which means the hassle and lengthening of the drawing work, so a drawing system that can solve this problem is required.

Accordingly, the present invention has been invented to solve the above problems, the numerical map that displays the location information of the reference point that can replace the function of the surface stones during aerial shooting in the image so that the operator does not need to go outside to check the surface stones The technical problem is to provide a GPS-based image processing system by setting the resolution of an image.

In addition, the technical task is to provide a GPS-based image processing system by setting the resolution of the digital map image to maintain a stable fixed regardless of the topographical characteristics of the position where the surface light emitter is used as a stone. .

According to an aspect of the present invention,

Cameras installed on the aircraft to shoot the ground,

A base fixed to the ground, a terminal protruding from the base to be supplied with power, a cover forming a hole opened to open the terminal and covering the base, a protective tube installed in the base to surround the terminal, Outlet consisting of a pair of doors are installed to open and close the upper end of the protective tube in a sliding manner and is elastically supported to close the protective tube at all times by a spring, the upper surface is inclined to move under pressure while contacting the terminals of the housing; It forms a tubular shape having a hollow, the lower end of the support is inserted and fixed in the hole, the terminal protruding formed at the lower end of the support and the terminal formed in the base electrically and physically detachably connected, the upper end in the radial axis A housing having rotatably fixed outer ring, an inner ring rotatably fixed about an axis of rotation disposed at right angles to the axis of rotation within the outer ring, and a plurality of hinges formed along a circumferential surface; A motor having a disk driven by electric power of a terminal and rotating up and down while rotating by the drive, and a propeller formed around the disk to lift the disk under lifting force during rotation; The laser beam is irradiated upward at various angles, and a plurality of lasers fixed to the inner ring, a linker drawn out below the laser, and a weight installed at the lower end of the linker to contact or spaced apart from the disc and bearings Light emitting means provided; Receiving module for receiving GPS position information while communicating with the aircraft, Positioning module for calculating the position of the aircraft relative to the current position of the surface light emitter in accordance with the position information, Sending to send the position information of the aircraft confirmed by the positioning module Positioning means having a module; A power distribution module for distributing the power of the terminal to the motor and the light emitting means; A control module for controlling ON / OFF of the motor in accordance with the position information sent from the positioning means; A first bed having a shaft connected to the hinge and having a thread formed on the circumferential surface thereof, a second hole having a rotating hole formed on the cross section and a thread formed in the opposite direction to the first screw thread formed on the circumferential surface thereof; A connecting tube including a connecting pipe having a female thread corresponding to the screw thread, a rotating rod rotatably inserted into a rotating hole, and a first rotating ring formed opposite to the rotating rod, wherein A plurality of support legs consisting of a connecting plate and a seat plate fixed to the ground by a first rotating ring and a second rotating ring rotatably fixed; And a cushion which is embedded in the housing so as to surround the laser and is filled with a viscous fluid to cushion the vibration of the laser.

An image DB for storing aerial photographing image data captured by the camera, composite image data, and edited drawing image data; An input module for receiving the aerial photographing image data from a camera; A synthesis module for editing a single integrated image by connecting a plurality of aerial photographing images to have continuity, and matching and matching laser beam images overlapping each other in neighboring aerial photographing images; A drawing module for drawing and editing a drawing image based on the integrated image; An output module for outputting the aerial photographing image, the integrated image or the drawing image so that a worker can see it; And a coordinate processing module for synthesizing GPS information to the drawing image to complete a numerical map, and synthesizing the position coordinates of the GPS information according to a corresponding position of a laser beam image. And a coordinate checking module that checks whether the actual position of the slit light emitter coincides with the GPS coordinates of the corresponding laser light image in the digital map synthesized by the coordinate processing module and, if there is a mismatch, displays the drawing image on which the laser light image is displayed. Map Editor

GPS-based image processing system by setting the resolution of the digital map image including a.

According to the present invention, it is possible to confirm the reference point from the aerial photographing image collected by aerial photographing by means of a light emitting emitter installed at a designated location on the ground, and to confirm the reference point, and to synthesize the aerial photographing image and the drawing image based on the confirmed reference point. There is an effect that can increase the accuracy and convenience of drawing, GPS information synthesis, etc.

1 is a block diagram showing a state of a processing system according to the present invention;
Figure 2 is an image showing the aerial image of the surface light emitter photographed in the aerial camera,
3 is an exploded perspective view showing the appearance of a light emitter for a pavement in accordance with the present invention;
4 is a view schematically showing the interlocking state of the motor and the light emitting means according to the present invention;
Figure 5 is a cross-sectional view schematically showing the inside of the housing of the light emitting emitter for stone according to the invention,
Figure 6 is a view showing the operation of the light emitter for a stone according to the invention,
7 is a cross-sectional view schematically showing the operation of the door,
8 is a view schematically showing the installation of the surface light emitter according to the present invention.

The above-described features and effects of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, and thus, those skilled in the art to which the present invention pertains may easily implement the technical idea of the present invention. Could be. As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosure, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

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

Figure 1 is a block diagram showing the appearance of the processing system according to the present invention, Figure 2 is an image showing the aerial image of the surface light emitter photographed by the aerial camera, it will be described with reference to this.

The treatment system according to the present invention is installed on the aircraft (A; see FIG. 6) and the camera 100 for photographing the ground, and the surface light emitter is installed at a specific point of the ground to irradiate the laser light toward the camera 100 ( 200 and a map editor 300 that receives the aerial photographed image of the camera 100 and processes the image.

Camera 100 may be applied to a well-known equipment dedicated to aerial photography, and a device supporting a resolution of 4520 × 2540 (11 million pixels) may be applied to maintain a high resolution for a shooting target even when shooting at a high altitude. Can be. In addition, the high speed aircraft (A) should be able to shoot 50 ~ 60 frames per second to collect images for a particular area.

In general, the aerial photographing-only camera 100 is arranged in a variety of angles, so that a plurality of cameras 100 are arranged at various angles so as to collect the photographed images of various directions and angles during one flight of the aircraft (A) At one point, the ground can be photographed in various directions.

The performance of the camera 100 according to the present invention may be sufficient to check and photograph the laser light of a relatively low output irradiated from the surface light emitter 200 even at a high altitude.

The surface light emitter 200 is installed at a specific point on the ground to irradiate the laser light toward the camera 100 installed in the aircraft A during aerial photography. The laser light irradiated from the surface light emitter 200 is irradiated at a low power within 1 to 20 W for safety, and the surface light emitter 200 emits a plurality of laser lights at a time to increase the photographing probability of the camera 100. It is composed.

The installation position of the pavement light emitter 200 is designated through accurate position checking and verification, and the corresponding position is used as the ground reference point when the digital map is produced. In the present invention, since the operator does not have to directly visit the site where the relevant stone is buried through the surface light emitter 200, it is possible to arrange a large number in a specific area such as the downtown area, and through this complex urban area Since various ground control points can be arranged and used in the system, it is effective to increase the accuracy and reliability of the digital map produced based on this.

Meanwhile, the surface light emitter 200 is detachable from the outlet 210 for supplying power and the housing 220 in which the various devices for irradiating the laser light are embedded, so that the housing containing the device only during aerial photography ( 220 may be connected to the outlet 210 to be used. Therefore, since the equipment in the relatively expensive housing 220 need not be manufactured and installed wherever the pavement is located, it can be installed and utilized at every aerial shooting, thereby minimizing the increase in the economic burden due to the increase of the pavement location.

Positioning means 250 is configured in the surface light emitter 200 to determine the position of the aircraft (A) to control whether or not the irradiation of the laser light and the irradiation angle of the laser light, a description thereof will be described below It explains in detail.

The map editor 300 receives the aerial photographed image captured by the camera 100 and proceeds the drawing based on the image. The image DB stores the aerial photographed image, the synthesized image, and the edited image image (numeric map image) data. 310, an input module 320 connected to the camera 100 to receive aerial photographing image data from the camera 100, and a single integrated image by connecting the aerial photographing image partially photographed on the ground to have continuity. The composition module 330 for editing, the drawing module 340 for drawing a drawing image that is the background of the numerical map based on the integrated image, and the operator can see the aerial image or the integrated image or drawing image An output module 350 for outputting the coordinate information, a coordinate processing module 360 for applying a GPS information to the drawing image to complete a numerical map, and GPS information synthesized with the drawing image. It consists of a coordinate check module 370 to check whether the drawing image error.

The input module 320 is a conventional data communication means for receiving aerial photographic image data by wire or wirelessly. The input module 320 may be connected to the camera 100 through a publicly-known or public communication cable, or may be built in the camera 100. It may read the memory and store the recorded data, or may be connected through a short range communication method such as Bluetooth or Zigbee.

The synthesizing module 330 is a means for allowing the operator to edit a plurality of aerial photographing images by editing an aerial photographing image output in a frame unit output through the output module 350, and the resolution of the aerial photographing image which is integrally connected to each other. A typical application that can edit the same size and the like, and combine them with each other and edit them into one integrated image may be applied.

Here, as shown in FIG. 2, a laser beam irradiated from the surface light emitter 200 is photographed in the aerial photographing image, and the laser beam images a, b, c, and d photographed in this way have an accurate position record. Using this as the ground reference point, the aerial photographing image is synthesized. Of course, since the position error with respect to the edge portion of the aerial image is increased according to the shooting altitude of the aircraft (A), only the effective range of the center portion of the aerial image is utilized in the synthesis of the aerial image, It will be apparent that only the laser light images a, b, c, and d within the effective range are used as ground reference points.

Since the synthesizing of aerial photographs is a well-known and public technique of drawing, a description of a detailed process and application theory for synthesizing aerial photographs is omitted.

The drawing module 340 works as a drawing image that is a background of a numerical map based on the composite image. When a road and a specific artificial structure are designated in the composite image, the drawing module 340 is based on the designated road and artificial structure. 340 completes the drawing image by drawing the drawing circle diagram. In this case, the position of the laser light image (a, b, c, d) of the surface light emitter 200 is displayed on the drawing image, and may be used as a reference when synthesizing GPS coordinates by the coordinate processing module 360.

Subsequently, the drawing module 340 includes a function of editing a drawing image drawn with a drawing source and completing the final drawing image. That is, the worker conducts field research with the drawing garden figure to identify the width and location of the roads and facilities, and confirms the correction target based on the drawing. Finally, the drawing drawing can be edited as the final drawing image. .

The drawing is a mechanical method for drawing directly onto a drawing paper and an image drawing method for drawing into an image image. Currently, the image drawing method is widely used, and the drawing module 340 according to the present invention applies an image drawing method.

Since the drawing of the drawing module 340 based on the composite image is a well-known and public technique, description of a detailed process and application theory for drawing the drawing image will be omitted.

The output module 350 may output the aerial image and the composite image of the synthesis module 330 and the image of the drawing module 340, and a general monitor may be applied.

The coordinate processing module 360 synthesizes the GPS coordinates with the drawing image completed by the drawing module 340 while interworking with the GPS, and adjusts the GPS coordinates based on the photographing position of the laser light image (a, b, c, d). Final synthesis of drawing image and GPS coordinates. That is, since the light emission point of the laser light is a rock position where the position coordinates are recorded accurately, the position coordinates of the GPS coordinates are synthesized with each other in accordance with the laser light images a, b, c, and d.

The coordinate checking module 370 checks the GPS coordinates and the drawing image synthesized with each other to check whether the drawing image is an error, and checks the position and GPS coordinates of the laser light images a, b, c, and d displayed on the drawing image. Compare and confirm the error. In more detail, since the laser light images (a, b, c, d) are photographed by the laser light emitted from the light emitter 200 for the surface installed at the correct position, the laser light images (a, b, c, d) should be present at the corresponding positions on the digital map. When synthesizing the GPS coordinates, the position and the GPS coordinates must naturally coincide. That is, if the position of the surface light emitter 200 is (43.567, 123.527), the corresponding GPS coordinates of the laser beam images (a, b, c, d) synthesized in the drawing image must also match (43.567, 123.527). .

The coordinate checking module 370 displays the drawing image on the drawing image when the position of the light emitting unit 200 and the GPS coordinates of the laser light images a, b, c, and d displayed on the drawing image do not match. Allow re-editing to proceed. This re-editing may be used to upgrade an existing drawing image, and if the position of the surface light emitter 200 is adjusted, this may be reflected in the drawing image.

3 is a perspective view illustrating an exploded view of the surface light emitter according to the present invention, and FIG. 8 schematically illustrates an installation of the surface light emitter according to the present invention.

The surface light emitter 200 according to the present invention includes an outlet 210 for supplying power, a housing 220 for protecting the motor 230 and the light emitting means 240, a motor 230, and a light emitting means 240. ), A power distribution module 260 (see FIG. 5), a control module 270 (see FIG. 5), a plurality of support legs 280 and 280 ′ limiting the inclination of the housing 220, and light emitting means 240. And a cushion 290 for delaying while suppressing vibration.

The outlet 210 is fixedly installed at the exact position designated as the stone. At this time, since the outlet supports the entire surface light emitter 200 to be stably fixed, it should be made to be firmly fixed at the corresponding position. Typically, the surface light emitter 200 according to the present invention is applied to downtown, and it may be preferable to be installed on the roof of a building B (see FIG. 6) in order to increase the efficiency of aerial photography. Meanwhile, the outlet 210 receives power supplied from the building B to secure power required for driving the motor 230 and the light emitting unit 240.

More specifically, the structure of the outlet 210, the outlet 210 has a base 211 fixed to the building (B), a terminal 212 protruding from the upper surface of the base 211, the terminal 212 Hole 213a is formed to open the cover 213 and covers the base 211, the protective tube 216 is installed in the base 211 to protect the terminal 212 and the upper end of the protective tube 216 It consists of a pair of sliding doors 217 and 217 'which open and close an opening.

The terminal 212 may be formed at an upper end of the stand 211a protruding from the base 211, and may be connected to a distribution line drawn from the building B to be energized. On the other hand, the terminal 212 should be a structure that can be attached and detached smoothly with the terminal 222 formed in the housing 220 when detachable between the housing 220 and the outlet 210, in the embodiment according to the present invention applies a screw method did. That is, the core is formed on the coaxial and the terminals 212 and 222 can be fastened to each other by a screw method, so that the electrical / physical detachment is performed smoothly.

In addition, a general plug type may be applied to the terminals 212 and 222. Terminals 212 and 222 according to the present invention can be any removable structure while providing power to the motor 230 and the light emitting means 240, it is not limited to the present embodiment.

The cover 213 forms a hole 213a into which the terminal 222 of the housing 220 can be inserted, and covers the base 211 to protect the terminal 212 formed in the base 211. Therefore, when the housing 220 is separated, the terminal 212 is prevented from being shorted due to rain or the like. To this end, the hole 213a should be opened and closed through a separate plug (not shown).

The protective tube 216 wraps and protects the stand 211a and the terminal 212 protruding from the base 211, and blocks the inflow of foreign substances that may cause a short circuit and a short circuit. To this end, the protective tube 216 is formed higher than the terminal 212 to minimize the exposure of the terminal 212 to the outside. On the other hand, the upper end of the protective tube 216 so that the terminal 222 of the housing 220 can be inserted.

The doors 217 and 217 'open and close the opened upper end of the protective tube 216, and the pair operates in a sliding manner. Referring to Fig. 7 (sectional view schematically showing the operation of the door), the doors 217 and 217 'are fixed to the protective tube 216 via a spring 217a, so that the pair are engaged with each other. To be maintained. Therefore, when there is no external force, the pair of doors 217 and 217 'closes the upper end of the protective tube 216 while keeping the state engaged with each other as shown in FIG.

Subsequently, an inclined surface 217b is formed on the upper surfaces of the doors 217 and 217 'so as to be pushed in engagement with the terminal 222 of the housing 220. Therefore, when the terminal 222 of the housing 220 is inserted through the hole 213a to be engaged with the doors 217 and 217 ', the pressure of the terminal 222 is applied to the inclined surface 217b and with FIG. 7 (b). Similarly, the doors 217 and 217 'move horizontally. As a result, the pressure of the continuous housing 220 moves the doors 217 and 217 'to completely open the protective tube 216 as shown in FIG. 7 (c) and through the top of the opened protective tube 216, the housing 220 Terminal 222 is inserted into and connected to the terminal 212 of the outlet 210.

On the other hand, when the terminal 222 of the housing 220 is separated from the protective tube 216 after being separated from the terminal 212 of the outlet 210, the pair of doors 217, 217 by the elasticity of the spring 217a ') Moves in contact with each other while the protective tube 216 is closed again.

The housing 220 is a tubular shape having a hollow, and a support 221 is inserted into the hole 213a at the lower end of the housing 220 to protrude, and a terminal 212 of the outlet 210 is formed at the lower end of the support 221. A terminal 222 to be connected is formed.

Subsequently, the upper end of the housing 220 is rotatably centered on the outer ring 223 which is rotatably fixed in the radial direction as the rotation axis, and the rotation axis disposed at right angles to the rotation axis inside the outer ring 223. A fixed inner ring 224 is constructed.

The outer ring 223 and the inner ring 224 are fixed to the upper end of the light emitting means 240, so that the irradiation direction of the light emitting means 240 can be variously aimed, a description thereof will be described in detail below.

A plurality of hinges 225 are formed on the circumferential surface of the housing 220. The hinge 225 is rotatably fixed to the support legs 280 and 280 ′ which are radially disposed along the circumference of the housing 220.

The motor 230 includes a disk 231 and a propeller 232 protruding around the disk 231. The disk 231 is applied with an elastic rubber material having a high friction coefficient on its upper surface, and rotates by the motor 230. The propeller 232 raises the disk 231 upward by receiving lift when the disk 231 rotates, such that the weight 243 of the light emitting unit 240 and the disk 231 come into contact with each other. Operation of the motor 230 and the interlocking structure of the light emitting means 240 will be described in detail below.

Reference numeral “233” denotes a “base” for fixing the motor 230 to the housing 220, and supports the motor 230 to be integral with the housing 220.

The light emitting unit 240 is installed at a lower end of the linker 242 and the plurality of lasers 241 aimed in various directions and fixed to the inner ring 224, the linker 242 drawn out below the laser 241. It consists of a weight 243. At the lower end of the weight 243, a bearing 243a is formed to prevent the weight 243 itself from receiving the rotational force of the disk 231 when engaged with the disk 231.

The laser 241 may be composed of a main laser aimed to irradiate a laser light directly upward, and a plurality of auxiliary lasers arranged around the main laser and aimed at a predetermined angle. The laser 241 is preferably to be able to irradiate the laser light with a sufficient output that can be taken by the camera 100 located remotely, for this purpose the output of the laser light can be typically limited to 1 ~ 20W.

A weight 243 having a constant weight is fixed to the lower end of the linker 242, so that the laser 241 always aims the laser light in a direction opposite to the direction of gravity under the load of the weight 243, thereby firing. Therefore, even if the position of the housing 220 is inclined by an external force, the main laser and the auxiliary laser can accurately irradiate a laser beam toward the camera 100 of the aircraft A.

The positioning module 250 confirms the current position of the aircraft A while communicating with the aircraft A in real time, and emits light when the aircraft A is located close to the light emitting unit 200 for the surface of the aircraft. It is possible to control the operation of the motor 230 to accurately irradiate the laser light irradiated directly from the means 240.

The power distribution module 260 distributes the power supplied from the outlet 210 to the motor 230 and the light emitting means 240, and a conventional power distribution technology is applied.

The control module 270 controls the ON / OFF of the motor 230 while communicating with the positioning module 250.

The support legs 280 and 280 'are rotatably fixed to one end of the hinge stand 225 and the other end is in close contact with the ground, and a shaft 281a connected to the hinge stand 225 is formed and formed on the circumferential surface thereof. A pipe for connecting the first set 281 with a thread formed therein, the second set 282 having a threaded portion formed in the circumferential surface with a rotation hole 282a formed in the cross section, and the first and second sets 281 and 282 connected to each other. A connecting pipe 283 having a female thread corresponding to the screw thread formed on the inner surface thereof, a rotating rod 284a rotatably inserted into the rotating hole 282a, and a first rotating ring formed to face the rotating rod 284a. A mounting plate 285 fixed with the connecting body 284 and seated on the ground through a connecting body 284 composed of 284b and a second rotating ring 285a rotatably fixed to the first rotating ring 284b. It is composed of Here, the threads formed on the first and second units 281 and 282 are right and left threads, so that the first and second units 281 and 282 are adjacent to each other according to the same direction of rotation of the connecting pipe 283. While being spaced apart so that the entire length of the support legs (280, 280 ') can be adjusted. Of course, the female thread formed in the connecting pipe 283 should also be formed of a thread in a direction corresponding to the right and left threads of the thread. For reference, the seating plate 285 may be preferably formed of a material or a shape having high friction with the ground.

As a result, the plurality of support legs 280 and 280 'are rotated and arranged around the hinge 225 according to the surrounding topography where the light emitting emitter 200 is located, and then the length of the connecting tube 283 is rotated. Since the housing 220 may be vertically adjusted by adjusting, the restriction on the installation position of the surface light emitter 200 may be minimized, and the housing 220 may be inclined while the laser surface light emitter 200 is in operation. The problem that the aiming direction of the light is distorted can be prevented. In addition, since the inclination of the housing 220 can be adjusted through the rotation of the connector 283, there is an effect of adjusting the fine aiming direction of the laser light.

The cushion 290 is a tube embedded in the housing 220 so as to surround the laser 241. The cushion 290 is filled with a viscous fluid 291 to suppress vibration of the laser 241. Therefore, when the laser 241 is rotated and vibrated by the driving of the motor 230, the cushion 290 minimizes this to suppress afterimages of the laser light emitted by the laser 241, thereby photographing the camera 100. The shape of the laser beam to be clarified can be made clear. In addition, even when the operation of the motor 230 is stopped, the vibration of the laser 241 can be quickly extinguished.

In addition, since the cushion 290 forms a viscous fluid 291 filled in the tube, there is no interference in the movement path of the laser 241. In addition, the cushion 290 absorbs the vibration of the laser 241 as well as buffers the shock caused by the rotation of the motor 230, thereby improving the accuracy of the laser light irradiated from the laser 241.

The tube constituting the cushion 290 is made of an elastic material such as rubber, and the viscous fluid 291 filled in the tube may be applied with a synthetic resin such as lubricant or lease.

Figure 4 is a view schematically showing the interlocking state of the motor and the light emitting means according to the present invention, Figure 5 is a cross-sectional view schematically showing the inside of the housing of the light emitter for stone surface according to the present invention, Figure 6 is a present invention FIG. Is a view illustrating an operation of the pavement light emitter according to the present invention.

As shown in Fig. 4A, when the motor 230 does not operate, the disk 231 does not rotate and does not contact with the weight 243, either.

The positioning unit 250 includes a receiving module 251 for communicating with the aircraft A, a positioning module 252 for checking the GPS position information transmitted by the aircraft A and calculating the position of the current aircraft; Consists of the outgoing module 253 for transmitting the location information of the confirmed aircraft (A) to the light emitting device 200 for the surface.

The receiving module 251 receives the location information from the aircraft located in S1 or S3, and the positioning module 252 checks the current position of the corresponding aircraft by comparing the calculated position with the position of the corresponding light emitter 200. The outgoing module 253 transmits the location information of the aircraft thus identified to the control module 270 of the light emitting device 200.

The control module 270 receives the position information transmitted from the transmission module 253 and controls the ON / OFF of the motor 230 to operate as shown in FIG. 4 (b).

As a result, the disk 231 is rotated by the operation of the motor 230, and the disk 231 is brought into contact with the weight 243 by the lifted propeller 232. At this time, while the bearing 243a is configured at the lower end of the weight 243, the disk 231 and the weight 243 are engaged through the bearing 243a. Therefore, the weight 243 moves along the disk 231 by the rotation of the disk 231, and the movement is transmitted to the laser 241 through the linker 242, so that the laser light irradiation range of the laser 241 is expanded. do. In this case, since the laser 241 is fixed to the housing 220 by the outer ring 223 and the inner ring 224, the laser 241 may smoothly rotate without interference along the rotation of the weight 243.

Subsequently, when the receiving module 251 receives the position information from the aircraft A located in S2, the positioning means 250 processes according to the above-described process and the control module 270 receives the final information of the aircraft A. Send location information.

The control module 270 stops the operation of the motor 230 in order to allow the camera 100 of the aircraft A located directly above to receive the laser light at one point. This is because when the laser 241 rotates, the position of the surface stone is not accurately recorded because it is photographed by the camera 100 in a relatively large circle.

As a result, the disk 231 is lowered while stopping its rotation, and the weight 243 is no longer receiving power, so the laser 241 aims in a direction opposite to gravity by gravity, and thus the laser 241. ) Irradiates a laser beam toward the aircraft A located directly above. Of course, the control of the control module 270 sets the range differentially according to the altitude of the aircraft A around the light emitting unit 200 for the surface of the light, and if the aircraft A enters the corresponding range, the control of the above-described form is performed. It was done.

In the detailed description of the present invention described above with reference to the preferred embodiments of the present invention, those skilled in the art or those skilled in the art having ordinary skill in the art will be described in the claims to be described later And it will be understood that various modifications and changes of the present invention can be made without departing from the scope of the art.

100; Camera 200; Light emitter 210 for pavement; Outlet
220; Housing 230; Motor 240; Light emitting means
250; Positioning means 260; Power Distribution Module
270; Control module 300; Map Editor 310; Image DB
320; Input module 330; Synthesis module 340; Drawing module
350; Output module 360; Coordinate Processing Module

Claims (1)

Camera 100 is installed on the aircraft (A) to shoot the ground,
A base 211 fixed to the ground, a terminal 212 protruding from the base 211 to supply power, and an opening 213a opened to open the terminal 212, and the base 211 is formed. The cover 213, the protective tube 216 is installed in the base 211 to surround the terminal 212, the upper end of the protective tube 216 and the upper end of the protective tube 216 is installed to open and close in a sliding manner and to the spring 217a Outlet consisting of a pair of doors (217, 217 ') formed by the support tube 216 is closed and closed to always close and the inclined surface (217b) formed in contact with the terminal 222 of the housing 220 under pressure 210; It forms a tubular shape having a hollow, and at the lower end of the support 221 is inserted into the hole 213a and fixed, and protrudingly formed at the lower end of the support 221 and electrically / physically with the terminal 212 formed in the base 211. Removably connected terminal 222, the upper end of the outer ring 223 rotatably fixed with a radial axis as a rotation axis, and the inner side of the outer axis rotating shaft disposed at right angles to the rotating shaft A housing 220 having a rotatably fixed inner ring 224 and a plurality of hinges 225 formed along a circumferential surface thereof; The disk 231 which is driven by the electric power of the terminals 212 and 222 and which is moved up and down while rotating by the driving, is formed around the disk 231 and receives lift force during rotation to form the disk 231. A motor 230 having a propeller 232 to raise; The laser beam is irradiated upward at various angles and fixed to the inner ring 224, a plurality of lasers 241, a linker 242 drawn out below the laser 241, and a lower end of the linker 242 are installed. Light emitting means 240 having weights 243 contacting or spaced apart from each other by the descending disk 231 and the bearing 243a; A receiving module 251 for receiving GPS position information while communicating with the aircraft A, a positioning module 252 for calculating the position of the aircraft A relative to the current position of the light emitter for the pavement according to the position information, and a position Position checking means 250 having a transmission module 253 for transmitting the position information of the aircraft (A) confirmed by the confirmation module 252; A power distribution module 260 for distributing the power of the terminals 212 and 222 to the motor 230 and the light emitting means 240; A control module 270 for controlling ON / OFF of the motor 230 according to the position information transmitted from the positioning means 250; A first base 281 formed with a shaft 281a connected to the hinge 225 and having a thread formed on the circumferential surface thereof, and a rotating hole 282a formed on the end surface thereof, and a thread of the first stage 281 formed on the circumferential surface thereof. A second tube 282 having a thread formed in a direction opposite to the first side; a connecting tube 283 having a female thread corresponding to the thread formed on an inner surface thereof while forming a tube shape connecting the first and second units 281 and 282 with each other; A connecting body 284 composed of a rotating rod 284a rotatably inserted into the rotating hole 282a, a first rotating ring 284b formed to face the rotating bar 284a, and a rotating portion with the first rotating ring 284b. A plurality of support legs 280 and 280 'composed of a connecting body 284 and a seating plate 285 fixed to the ground via a second rotating ring 285a which is fixedly possible; And a cushion 290 embedded in the housing 220 to surround the laser 241 and filled with a viscous fluid 291 to cushion vibration of the laser 241.
An image DB 310 for storing aerial photographing image data captured by the camera 100, composite image data, and edited drawing image data; An input module 320 for receiving the aerial photographing image data from a camera 100; Combining a plurality of the aerial photographing image to have a continuity, edited into a single integrated image, the synthesis module 330 for matching and connecting the overlapping laser light images (a, b, c, d) of the neighboring aerial photographing image ; A drawing module 340 for drawing a drawing image based on the integrated image and editing the drawing image; An output module 350 for outputting the aerial photographed image, the integrated image, or the drawing image to be visible to a worker; A coordinate processing module 360 for synthesizing GPS information to the drawing image to complete a numerical map, and synthesizing the position coordinates of the GPS information according to a corresponding position of a laser beam image (a, b, c, d); And the GPS coordinates of the laser light images (a, b, c, d) in the numerical map synthesized by the coordinate processing module 360 and the actual position of the light emitter 200 for the headstone. Map editor 300 of coordinate checking module 370 that displays a drawing image on which the laser light image (a, b, c, d) is displayed
GPS-based image processing system through the resolution setting of the digital map image comprising a.

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