KR101988212B1 - Surveying system using unmanned aerial vehicle and method using the same - Google Patents

Abstract

Disclosed is a surveying system using an unmanned aerial vehicle (UAV) which includes an aerial photo signal functioning as a ground control point in surveying using an aerial photo and a method thereof. According to the present invention, the surveying system using an UAV comprises: a first UAV including a GPS reception unit to collect GPS information when landing on a preset target point and including an aerial photo signal unit capable of being identified in the air to function as a ground control point during photogrammetry; a second UAV flying a preset route including a preset area and collecting photo information including an aerial photo of the preset area; and a server controlling the first and second UAVs, receiving GPS information and the photo information from the first and second UAVs, and performing the photogrammetry based on the received GPS and photo information. Accordingly, coordinates of the aerial photo can be acquired without separately surveying a ground control point, and it is not required to manually move or install an aerial photo signal and separately survey coordinates, thereby easily acquiring coordinates of the aerial photo.

Description

Technical Field [0001] The present invention relates to a surveying system using an unmanned aerial vehicle,

The present invention relates to a surveying system and method using an unmanned aerial vehicle, and more particularly, to a surveying system and method using an unmanned aerial vehicle equipped with an air marker to serve as a ground reference point for aerial photographing.

Mapping and surveying through aerial photographing is performed by taking an aerial photograph of the target area and then converting it from the spatial coordinate system of the photograph to the coordinate system of the actual object area.

In order to give precise coordinates to the aerial photograph, a facial expression operation is performed. This involves an inner facial expression step of reflecting the optical environment at the time of photographing by matching photographs, performing focal length correction, , Which is divided into an outer facial expression phase in which the geometric relationship between a plurality of continuous photographs is converted into an actual three-dimensional coordinate using at least six ground reference point data.

Conventionally, in order to acquire such ground reference point data, it is necessary to select a reference point for the actual topography of the airline business and to acquire the actual coordinates of the ground reference point through the precise surveying method such as total station or GPS surveying, there was.

In order to solve such a problem, Korean Patent No. 10-0915600 discloses a method in which an airtight marker that is distinguishable from an aerial image is installed at a reference point having three-dimensional coordinates and used as a ground reference point, And provides a technique for acquiring three-dimensional coordinates.

However, this is also a difference between before and after image capturing compared to the conventional method, and it is a problem that time and cost problems can not be improved because the coordinates need to be measured by moving to the reference point and installing the air cover mark.

Therefore, it is possible to acquire the coordinates of aerial photographs without using a separate ground reference point coordinate measurement by using the air reference mark as a ground reference point. However, it is required to search for a method of installing the air star cover and measuring the coordinates more easily do.

Korean Patent No. 10-0915600 "Method for measuring three-dimensional coordinates of an image using ground reference point mark"

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for use of a landmark as a ground reference point, And to obtain a coordinate of an aerial photograph, and a method and a system for using the unmanned aerial vehicle.

According to another aspect of the present invention, there is provided a surveying system using an unmanned aerial vehicle, comprising: a GPS receiver for collecting GPS information when landing at a preset target point; A first unmanned aerial vehicle serving as a ground control point; A second unmanned aerial vehicle for collecting photograph information including an aerial photograph of the predetermined area by flying a predetermined route including a predetermined area; And controlling the first unmanned aerial vehicle and the second unmanned aerial vehicle, receiving the GPS information and the photograph information from the first unmanned aerial vehicle and the second unmanned aerial vehicle, and performing photogrammetry based on the received GPS information and photograph information And a server to perform the operation.

At this time, in the first unmanned air vehicle, the air defense cover is provided so as to be able to fly in a folded state, and when folded in flight, when the first unmanned air vehicle landed at the target point, the folded cover part is unfolded .

The first unmanned aerial vehicle includes a plurality of landing portions protruding from the lower side of the first unmanned aerial vehicle in the direction of the ground to bear the load of the first unmanned aerial vehicle at the time of landing, And a gyro sensor unit for measuring horizontal information which can identify a tilted degree and a tilted direction of the first unmanned aerial vehicle landed at the target point, and measuring the horizontal information to adjust the length of the plurality of landing units Can be maintained independently of the state of the ground on which the first unmanned aerial vehicle landed so that the air conditioner can be in a horizontal state.

In addition, the server identifies the air cover marker included in the received photograph information, and determines coordinates of the center of the air marker marker using the received GPS information, thereby performing measurement of the received photograph information can do.

And the server sets the target point to have a coordinate value set at a random setting within the predetermined area, and when the first unmanned aerial vehicle has a plurality of targets, each target point of the plurality of first unmanned aerial vehicles The distance between each of the target points may be set to be equal to or greater than a predetermined distance.

The server may set the target point to have a coordinate value set at random within the predetermined area, and when the first unmanned air vehicle has a plurality of targets, the target points of the plurality of first unmanned aerial vehicles are different from each other Wherein the GPS receiver receives GPS information from a plurality of first unmanned aerial vehicles in the order of landing at the respective target points, and when GPS information is received from any one first unmanned aerial vehicle, Wherein the first unmanned aerial vehicle includes a plurality of first unmanned aerial vehicles and a plurality of first unmanned aerial vehicles, The first unmanned aerial vehicle can fly again to the reset target point and land.

When the target point is reset, the server determines, based on the position included in the GPS information of the first unmanned aerial vehicle, the position of the first unmanned aerial vehicle among the positions included in the GPS information of the first unmanned aerial vehicle The target point may be reset to the opposite direction to the position of the first unmanned aerial vehicle nearest to the first unmanned aerial vehicle and to be greater than or equal to the predetermined distance from the position of the nearest first unmanned aerial vehicle.

Also, the server may cause the first unmanned aerial vehicle to re-land and re-land the first unmanned aerial vehicle at a predetermined distance when the air parking mark is not identified in the received photograph information, The second UAV can re-collect the photo information.

According to another aspect of the present invention, there is provided a survey method using an unmanned aerial vehicle, comprising: setting a target point by a server; The first unmanned aerial vehicle having a landing sign capable of being identified in the sky up to the set target point and serving as a ground reference point during photogrammetry, Collecting GPS information through a GPS receiver provided with the first unmanned aerial vehicle landed and transmitting the GPS information to the server; When the GPS information is received by the server, setting a flight path of the second unmanned aerial vehicle by the server; Collecting photograph information of the predetermined area and transmitting the collected photograph information to the server, the second unmanned aerial vehicle flying along the set flight path; And when the photographic information is received by the server, photometric measurement is performed by the server based on the received GPS information and photographic information.

Thus, it is possible to acquire the coordinates of the aerial photograph without a separate ground reference point measurement, but it is unnecessary for the person to manually move or install the air cover, and there is no need for a separate coordinate survey, .

1 is a block diagram illustrating a surveying system using an unmanned aerial vehicle according to an embodiment of the present invention.
FIG. 2 is a view for explaining an air marker of a surveying system using an unmanned aerial vehicle according to an embodiment of the present invention. Referring to FIG.
FIG. 3 is a view for explaining an air marker of a surveying system using an unmanned aerial vehicle according to another embodiment of the present invention
4 is a view illustrating a landing unit of a surveying system using an unmanned aerial vehicle according to an embodiment of the present invention.
FIG. 5 is a flowchart illustrating a surveying method using an unmanned aerial vehicle according to an embodiment of the present invention.
6 is a flowchart illustrating a method of measuring an unmanned aerial vehicle according to another embodiment of the present invention.
FIG. 7 is a flowchart illustrating a method of measuring an unmanned aerial vehicle according to another embodiment of the present invention.
8 is a view illustrating a method of resetting a target point of a measurement method using an unmanned aerial vehicle according to another embodiment of the present invention.
FIG. 9 is a flowchart illustrating a method of measuring an unmanned aerial vehicle according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like reference numerals refer to like elements throughout the specification.

1 is a block diagram illustrating a surveying system using an unmanned aerial vehicle according to an embodiment of the present invention.

Hereinafter, a surveying system using an unmanned aerial vehicle (hereinafter referred to as a 'surveying system') according to the present embodiment will be described with reference to FIG.

The present surveying system is provided to acquire three-dimensional coordinates of aerial images more easily by installing separate air markers and using air markers that do not require coordinate measurement of air markers as ground reference points.

For this purpose, the surveying system includes a first unmanned aerial vehicle (100), a second unmanned aerial vehicle (200), and a server (300).

The first UAV 100 is included in the photograph information collected by the second UAV 200 and serves as a ground reference point for photogrammetry. For this purpose, the first UAV 100 is provided with a first driver 110, The first communication unit 160 and the first control unit 170. The first control unit 170 controls the operation of the gyro sensor unit 140, the landing unit 150,

The first driving unit 110 is provided to allow the first UAV 100 to fly and allow the server 300 to fly to a predetermined target point.

Specifically, the first driving unit 110 generates a drag force by rotating a plurality of rotating blades provided on the upper side of the first UAU 100, and causes the first UAU 100 to fly by the generated drag force can do.

The first GPS receiver 120 is provided to collect GPS information including the GPS coordinates when the first unmanned aerial vehicle 100 lands and fares to the target point.

The airbag cover 130 is included in the photograph information collected by the second unmanned aerial vehicle 200 so as to be identifiable in the sky so as to serve as a ground reference point in photogrammetry.

Specifically, the air defense marking unit 130 is displayed so as to be distinguishable from the sky, and is folded so that the first unmanned air vehicle 100 is in a folded state when the first unmanned air vehicle 100 is flying, When landing, it can be unfolded.

Here, a more detailed description of the airhead seal portion 130 will be described later with reference to Figs. 2 to 3. Fig.

The gyro sensor unit 140 may be provided to measure horizontal information capable of ascertaining the degree and direction in which the first unmanned aerial vehicle 100 is tilted.

The landing part 150 is provided for allowing the first unmanned aerial vehicle 100 to stably land at a target point and for loading the first unmanned air vehicle 100 at the time of landing, And protrude from the lower side of the substrate 100 in the direction of the paper surface.

In addition, the plurality of landing portions 150 are provided so that the length of the first unmanned air vehicle 100 can be maintained in a horizontal state regardless of the terrain on which the first unmanned air vehicle 100 is landed .

Hereinafter, a more detailed description of the landing part 150 will be given later with reference to FIG.

The first communication unit 160 may be provided to receive a control signal for causing the server 300 to fly to a predetermined target point and to transmit the GPS information to the server 300. [

The first control unit 170 controls the first driving unit 110, the first GPS receiving unit 120, the air marker unit 130, the gyro sensor unit 140, the landing unit 150, and the first communication unit 160 . ≪ / RTI >

Specifically, the first controller 170 may control the first driver 110 according to the control signal received from the server 300, thereby allowing the first driver 110 to fly to a predetermined target point.

The first controller 170 may receive GPS information of the first unmanned aerial vehicle 100 by the first GPS receiver 120 when the first unmanned air vehicle 100 lands.

The first controller 170 controls the airbag cover 130 to be folded when the first unmanned air vehicle 100 is flying and when the first unmanned air vehicle 100 lands at the target point, The airbag cover 130 can be opened.

When the first manned vehicle 100 lands on the target point, the first controller 170 collects the horizontal information through the gyro sensor unit 140 and outputs the collected information to the plurality of landing units 150 So that the first UAV 100 can be maintained in a horizontal state.

Also, the first controller 170 may control the first communication unit 160 to transmit the GPS information of the received first unmanned aerial vehicle 100 to the server 300.

Meanwhile, the second unmanned aerial vehicle 200 is provided for collecting photograph information of a predetermined area by flying the route set by the server 300. For this purpose, the second driver 210, the second GPS receiver 220, a photo collecting unit 230, a second communication unit 240, and a second control unit 250.

The second driving unit 210 is provided to allow the second unmanned air vehicle 200 to fly.

Specifically, the second driving unit 210 generates a drag force by rotating a plurality of rotating blades provided on the upper side of the second unmanned air vehicle 200, and causes the second unmanned air bag 200 to fly by the generated drag can do.

The second GPS receiver 220 is provided for collecting GPS information of the second unmanned aerial vehicle 200. The photograph collecting unit 230 is provided for photographing predetermined areas and collecting photograph information, The air marker cover 130 is photographed so as to be identifiable. So that the server 300 makes it a ground reference point when photographed.

The second communication unit 240 may be provided to receive the control signal from the server 300 and to transmit the collected photo information to the server 300. [

The second control unit 250 may be provided to control the second driving unit 210, the second GPS receiving unit 220, the photograph collecting unit 230, and the second communication unit 240.

The second controller 250 controls the second driver 210 according to the control signal received from the server 300 so that the second unmanned airplane 200 can fly the predetermined flight path .

The second controller 250 causes the second GPS receiver 220 to collect GPS information of the second unmanned aerial vehicle 200 so that the second unmanned aerial vehicle 200 is positioned within the predetermined flight path And if it is determined that the vehicle is not located within the predetermined flight path, the second communication unit 240 may transmit the departure alarm to the server 300.

The second control unit 250 determines whether the second unmanned object 200 is located within a predetermined area through the GPS information collected by the second unmanned aerial vehicle 200 in a predetermined flight path, If it is determined that the image is located within the set area, the photograph collecting unit 230 may photograph the aerial photograph of the predetermined area to collect the photograph information.

The second control unit 250 may cause the second communication unit 240 to transmit the departure warning and the collected photograph information to the server 300.

The server 300 controls the first and second unmanned aerial vehicles 100 and 200 and transmits the GPS information of the first unmanned air vehicle 100 and the second unmanned air vehicle 100 from the first unmanned air vehicle 100, 200, and is provided for performing photogrammetry based on the received photograph information and the GPS information of the first UAV 100. To this end, the third communication unit 310, the third control unit 320, and a storage unit 330.

The third communication unit 310 transmits control signals to the first and second unmanned objects 100 and 200 and receives the GPS information of the first unmanned object 100 from the first unmanned air vehicle 100 , And to receive photograph information and path deviation warning from the second unmanned aerial vehicle 200.

The third control unit 320 may set a target point of the first UAV 100 and cause the first UAV 100 to fly to the target point and land.

Here, the target point is set to have a coordinate value set at random in a predetermined area aiming at photographing, and when the first unmanned object 100 has a plurality of coordinates, It is possible to set the point to have a different coordinate value, but to calculate the distance between the respective target points so as to be spaced apart by a predetermined distance d0 or more.

Then, the third controller 320 sets the flight path of the second unmanned object 200 and allows the second unmanned object 200 to fly on the predetermined path.

Specifically, the third control unit 320 may include a predetermined area aiming at photographing in the flight path of the second unmanned aerial vehicle 200, or collect all the photograph information of a predetermined area targeted for photographing And the like.

The third controller 320 identifies the air marker cover 130 included in the photograph information received from the second unmanned aerial vehicle 200 and displays the received first It is possible to perform the measurement of the received photograph information by determining the coordinates using the GPS information of the UAV 100. [

For example, when a plurality of first unmanned aerial vehicles 100 are provided, the third control unit 320 assigns each unique code to a plurality of first unmanned aerial vehicles 100, and each first control unit 170 May include the unique code information in the GPS information of each first UAV 100 to be transmitted to the server 300 so as to distinguish the GPS information of each first UAV 100 have.

The third controller 320 controls the second unmanned aerial vehicle 200 to be positioned on the predetermined flight path again when the path deviation alarm is received through the third communication unit 310, If the second unmanned aerial vehicle 200 can not be located on the flight path, the second unmanned aerial vehicle 200 may be reconfigured to re-fly.

The storage unit 330 stores the GPS information of the first unmanned air vehicle 100 received from the first unmanned air vehicle 100 and the photograph information received from the second unmanned air vehicle 200, A unique code assigned to the first UAV 100 set by the third control unit 320, a target point of the first UAV 100 and a flight path of the second UAV 200, 3 < / RTI >

FIG. 2 is a view for explaining the air marking unit 130 of the measurement system according to an embodiment of the present invention, and FIG. 3 is a view showing the air marking unit 130 of the measurement system according to another embodiment of the present invention. Which is shown for illustrative purposes.

Hereinafter, the airhead cover 130 of the measurement system according to the present embodiment and another embodiment will be described with reference to FIGS.

The airhead cover 130 in this embodiment and another embodiment is included in the photograph information collected by the second unmanned aerial vehicle 200 as described above, and is provided to serve as a ground reference point in photogrammetry.

For this purpose, the airbag cover 130 is provided so that it can be stored in the first unmanned aerial vehicle 100 in a folded state, and the first unmanned air bag 100 is stored in a folded state during the flight by the first controller 170 When the first unmanned object (100) is landed at the target point, the first controller (170) controls the first unmanned object (100) So that the second unmanned aerial vehicle 200 can be included in the photo information collected by the unmanned aerial vehicle 200 as a ground reference point.

In this case, the airbag cover 130 may be provided in a plate shape as shown in FIG. 2. In this case, the airbag cover 130 and the body of the first UAV 100 are connected to each other, A connecting member (not shown) may be provided, the length of which is adjusted in the vertical direction so that the height of the air marker cover 130 can be adjusted.

When an illuminance sensor (not shown) is provided on the airbag cover 130 when the first UAV 100 is provided with a connecting member (not shown), and when the illuminance of the airbag cover 130 is less than a predetermined value, The length of the connecting member is made longer by the third control unit 320 so that the height of the airbag cover 130 is adjusted upwardly so that the image information collected by the second unmanned aerial vehicle 200 due to obstacles such as grass It can be prepared for cases where it is not identified.

3, the air bearing cover 130 is provided in the form of an umbrella as shown in FIG. 3, so that the first unmanned air vehicle 100 minimizes the resistance of the air in a folded state during flight, The airbag cover 130 is unfolded by the first controller 170 so as to be included in the photo information collected by the second unmanned aerial vehicle 200 so as to serve as a ground reference point.

In the case where the air defense cover 130 is provided in the form of an umbrella, a storage space (not shown) is provided inside the body of the first UAV 100, It is possible to reduce the resistance of the air that can be generated by the airbag cover 130 in flight so that the airbag cover 130 is completely or partially housed in the airbag cover 130 (not shown).

4 is a diagram illustrating a landing portion 150 of a surveying system according to an embodiment of the present invention.

Hereinafter, the landing portion 150 of the surveying system according to one embodiment and another embodiment will be described with reference to FIG.

The landing unit 150 may be provided to maintain the first unmanned object 100 in a horizontal state regardless of the terrain where the first unmanned aerial vehicle 100 is landed, as described above.

The landing part 150 measures the horizontal information of the first unmanned air vehicle 100 by the gyro sensor unit 140 when the first unmanned air vehicle 100 lands, The length of the landing portions 150-1 and 150-3 tilted to the lower side among the plurality of landing portions 150 is made longer and the landing portions 150-1 and 150-3 landing on the upwardly tilted side The length of the sections 150-2 and 150-4 is shortened so that the first unmanned aerial vehicle 100 is in a horizontal state irrespective of the ground surface on which the first unmanned air vehicle 100 lands, can do.

For example, the first control unit 170 controls the gyro sensor unit 140 to increase the length of the landing unit 150-1 on the side of the lowest one of the plurality of landing units 150, The horizontal information of the unmanned air vehicle 100 is measured in real time and the landing part 150-1 tilted to the lowest side is lengthened to change the horizontal information so that the landing part 150-3 on the other side The length of the landing portion 150-3 on the other side inclined downward is made long.

The first controller 170 repeats the above process until the first unmanned aerial vehicle 100 is in a horizontal state. The first controller 170 repeats the above process until the first unmanned air vehicle 100 reaches the horizontal position, The length of the landing portion 150-4 which is tilted most upward from the measured horizontal information is shortened so that the first unmanned air vehicle 100 can be in a horizontal state have.

If the first UAV 100 does not become horizontal after the above process, the first controller 170 causes the first UAV 100 to move and land by a predetermined distance d0, The first control unit 170 may make the lengths of the plurality of landing units 150 the same when the first unmanned air vehicle 100 lands.

FIG. 5 is a flowchart illustrating a surveying method using an unmanned aerial vehicle according to an embodiment of the present invention.

Hereinafter, with reference to FIG. 5, a method of measuring an unmanned aerial vehicle (hereinafter referred to as a 'surveying method') according to the present embodiment will be described.

In the present surveying method, first, the target point is set by the server 300 (S610), and the first unmanned aerial vehicle 100 reaches the set target point and lands (S620).

When the first unmanned air vehicle 100 lands on the first UAV 100, the GPS information is collected and transmitted to the server 300 in step S630. When the GPS information of the first UAV 100 is transmitted to the server 300, The second ROV 200 is set to a flight path of the second ROV 200 in step S640 and the second ROV 200 collects image information of a predetermined area by flying the set route and transmits the collected information to the server 300 ).

Then, the server 300 performs photogrammetry by matching the GPS information received from the first UAV 100 to the photo information received from the second UAV 200 in operation S660.

6 is a flowchart illustrating a method of measuring an unmanned aerial vehicle according to another embodiment of the present invention.

Hereinafter, a measurement method according to another embodiment will be described with reference to FIG.

First, when a plurality of first unmanned aerial vehicles 100 are provided, a target point number equal to the number of first unmanned aerial vehicles 100 may be set by the server 300 (S710).

At this time, the server 300 may randomly set a plurality of target points to have coordinate values within predetermined areas that require the measurement, and each target point may have a different coordinate value.

When a plurality of target points are set, the server 300 may determine whether the distance between the target points is equal to or greater than a predetermined distance d0 (S720).

If the distance between the target points is not equal to or greater than the preset distance d0 (S720-N), the distance between the target points of the target points other than one target point, The point can be reset (S710).

If the distance between each of the target points is equal to or greater than the predetermined distance d0 (S720-Y), a plurality of target points are assigned to the plurality of first UAV 100, (S730). ≪ / RTI >

At this time, the first unmanned aerial vehicle 100 can be given a code so as to be distinguishable from each other, and the received code can be added to the GPS information collected by each first UAV 100.

When each first unmanned aerial vehicle 100 lands, it collects and transmits each GPS information to the server 300 in step S740. The server 300 receives all the GPS information from all the plurality of first unmanned aerial vehicles 100 If it is received, the server 300 may set the flight path of the second unmanned aerial vehicle 200 (S750).

When the flight path is set by the server 300, the second unmanned aerial vehicle 200 collects photograph information of a predetermined area by flying the set flight path, and transmits the collected photograph information to the server 300 (S760) (Step S770). In step S770, the photographic information received from the second UAV 200 is photographed by matching the GPS information received from the first UAV 100.

FIG. 7 is a flowchart illustrating a method of measuring an unmanned aerial vehicle according to another embodiment of the present invention. FIG. 8 is a flowchart illustrating a method of measuring the unmanned aerial vehicle according to another embodiment of the present invention. In the following description.

Hereinafter, a method of measuring according to another embodiment will be described with reference to FIGS.

First, when a plurality of first unmanned aerial vehicles 100 are provided, the same number of target points as the plurality of unmanned aerial vehicles including any one first unmanned aerial vehicle 100 is set by the server 300 (S810).

At this time, the server 300 may randomly set a plurality of target points to have coordinate values within predetermined areas that require the measurement, and each target point may have a different coordinate value.

When a plurality of target points are set, a plurality of first unmanned aerial vehicles (100) including any one first unmanned aerial vehicle (100) fly to a target point and land (S820) A plurality of first UAVs 100 including the GPS receiver 100 may collect GPS information and transmit the collected GPS information to the server 300 (S830).

At this time, the plurality of first unmanned aerial vehicles (100) may transmit the respective GPS information to the server (300) in the order of landing at each target point.

The server 300 receives the GPS information from any one of the first unmanned aerial vehicles 100 and then receives the GPS information from the other first unmanned air vehicle 100 It is possible to determine whether the first unmanned air vehicle 100 landed first within the predetermined distance d0 and the first unmanned air vehicle 100 landed on the basis of the GPS information of the first unmanned air vehicle 100 in step S840.

When there is a first unmanned air vehicle 100 that is within a predetermined distance d0 from any one of the first unmanned air vehicles 100 that landed at step S840-Y, 100) (step S810).

For example, as shown in FIG. 8A, when the first unmanned flight vehicle 100-5 is located at a distance d1 shorter than the preset distance d0, The target point of one first unmanned aerial vehicle 100-5 is set again by the server 300 and the target point to be reset at this time is set by the server 300 to any one of the first unmanned air vehicles 100-5 in the direction opposite to the position of the first unmanned air vehicle 100-2 that is landed at the closest position to any one of the first unmanned aerial vehicles 100-5, The position of the first unmanned air vehicle 100-2 is reset to be the target point by a predetermined distance d0 or more from the position of the first unmanned air vehicle 100-2 landed on the ground, .

On the other hand, if there is no first unmanned aerial vehicle 100 landed within a predetermined distance d0 between the first unmanned air vehicle 100 and the first unmanned air vehicle 100 in step S840-N, The flight path of the air vehicle 200 can be set (S850), and the subsequent steps are performed in the same manner as the measurement method according to the other embodiment described above.

9 is a flow chart illustrating the method of measurement according to another embodiment of the present invention.

Hereinafter, a measurement method according to still another embodiment will be described with reference to FIG.

The method according to another embodiment of the present invention is a method in which the server 300 sets the target point of the first UAV 100 at step S910 and the second UAV 200 travels the flight path Up to the step of collecting the photographic information of the area and transmitting the information to the server 300 is performed in the same manner as the measuring method according to the embodiment described above.

However, the server 300 receiving the photo information from the second unmanned aerial vehicle 200 may determine whether the airhead cover 130 is identifiable to the received photo information (S960).

If a plurality of first unmanned aerial vehicles 100 are provided, it is possible to determine whether the airborne markers 130 are identifiable as many as the plurality of first unmanned aerial vehicles 100.

The server 300 can set the target point of the first UAV 100 again when the airhead cover 130 is not identifiable (S960-N) in the received photograph information.

Specifically, when the target point of the first UAV 100 is set again by the server 300, the server 300 resets the target point to a position within a predetermined distance from the current position of the first UAV 100 So that the re-flying and re-landing time of the first UAV 100 can be shortened.

In a case where a plurality of first unmanned aerial vehicles 100 are provided, the GPS information of each of the first plurality of unmanned air vehicles 100 includes code information assigned to each first unmanned aerial vehicle 100, It is possible to reset only the target point of the first UAV 100 where the marking unit 130 is not identified.

On the other hand, when the airhead cover 130 is identifiable (S960-Y), the server 300 transmits the photo information received from the second unmanned airplane 200 to the first unmanned air vehicle 100 The received GPS information may be matched to perform photogrammetry (S970).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: first unmanned aerial vehicle 110: first driving section
120: first GPS receiver 130:
140: Gyro sensor part 150: Landing part
160: first communication unit 170: first control unit
200: second unmanned aerial vehicle 210: second driving section
220: second GPS receiver 230:
240: second communication unit 250: second control unit
300: server 310: third communication section
320: third control unit 330:
d0: preset distance d1: distance shorter than preset distance

Claims (9)

A first unmanned aerial vehicle that collects GPS information when a GPS receiver is landed at a predetermined target point, and has an airtight cover that can be identified in the sky to serve as a ground reference point in photogrammetry;
A second unmanned aerial vehicle for collecting photograph information including an aerial photograph of the predetermined area by flying a predetermined route including a predetermined area; And
The control unit controls the first and second unmanned aerial vehicles and the second unmanned aerial vehicle, receives the GPS information and the photograph information from the first and second unmanned aerial vehicles, and performs photogrammetry based on the received GPS information and photograph information And a server,
The server comprises:
Setting the target point to have a coordinate value set at a random value within the predetermined area, and when each of the first unmanned aerial vehicles has a plurality of targets, setting each of the target points of the plurality of first unmanned aerial vehicles to have different coordinate values And receiving GPS information from a plurality of first unmanned aerial vehicles in the order of landing at the respective target points, wherein when GPS information is received from any one first unmanned aerial vehicle, The first unmanned aerial vehicle is reset if the first unmanned aerial vehicle that landed within a predetermined distance is present as compared with the GPS information of the first unmanned aerial vehicle, Let's fly again to the reset target point,
The server comprises:
Wherein when the target point of any one of the first unmanned aerial vehicles is reset, the position of the first unmanned aerial vehicle, which is included in the GPS information of the first unmanned aerial vehicle, The target point is reset to the opposite direction to the position of the first unmanned aerial vehicle nearest to any one of the first unmanned aerial vehicles and the target point is reset to the predetermined distance or more from the position of the nearest first unmanned air vehicle Photogrammetric system using unmanned aerial vehicle. The method according to claim 1,
The first unmanned air vehicle,
Wherein the airtight cover part is provided so as to be able to fly in a folded state and is folded when the airplane is in flight and the airtight cover part in the folded state is deployed when the first unmanned air vehicle landed at the target point Photogrammetry system. 3. The method of claim 2,
The first unmanned air vehicle,
A plurality of landing portions protruding from the lower side of the first UAV in order to bear the load of the first UAV when landing, and being adjustable in length; And
Further comprising: a gyro sensor unit for measuring the tilt of the first unmanned aerial vehicle landed at the target point and the horizontal information capable of ascertaining the tilted direction,
The first unmanned air vehicle,
The horizontal information is measured and the lengths of the plurality of landing parts are individually adjusted so that the horizontal state is maintained regardless of the state of the ground on which the first unmanned air vehicle landed, Photogrammetric system using unmanned aerial vehicle. The method according to claim 1,
The server comprises:
Wherein the controller performs the measurement of the received photograph information by identifying the air cover mark included in the received photograph information and determining the coordinates using the received GPS information at the central point of the identified air cover mark, Photogrammetry system using flight. The method according to claim 1,
The server comprises:
Setting the target point to have a coordinate value set at a random setting within the predetermined area, and when each of the first unmanned aerial vehicles has a plurality of targets, setting each of the target points of the plurality of first unmanned aerial vehicles to have different coordinate values , And a distance between the respective target points is spaced by a predetermined distance or more. delete delete The method according to claim 1,
The server comprises:
Wherein when the air navigation marker is not identified in the received photograph information, the first non-inflow vehicle re-bids the first non-inflight air vehicle by a predetermined distance, and when the GPS information is re-received from the re- And the second unmanned aerial vehicle causes the photograph information to be collected again. Setting a target point by a server;
The first unmanned aerial vehicle having a landing sign capable of being identified in the sky up to the set target point and serving as a ground reference point during photogrammetry,
Collecting GPS information through a GPS receiver provided with the first unmanned aerial vehicle landed and transmitting the GPS information to the server;
When the GPS information is received by the server, setting a flight path of the second unmanned aerial vehicle by the server;
Collecting photograph information of a predetermined area and transmitting the collected photograph information to the server, the second unmanned aerial vehicle flying along the set flight path;
When photographic information is received at the server, photometric measurement is performed by the server based on the received GPS information and photographic information; And
And setting, by the server, the target point to have a coordinate value set at random within the predetermined area, and when each of the first unmanned aerial vehicles has a plurality of target points, Wherein the GPS information is received from a plurality of first unmanned aerial vehicles in the order of landing at the respective target points, and when GPS information is received from any one first unmanned aerial vehicle, The first target point of the first unmanned aerial vehicle is reset if there is a first unmanned aerial vehicle landed within a predetermined distance as compared with the GPS information of the first unmanned aerial vehicle received midway, 1, causing the unmanned aerial vehicle to fly again to the reset target point,
The step of resetting the target point so as to fly again to the reset target point,
Wherein when the target point of any one of the first unmanned aerial vehicles is reset by the server, based on a position included in the GPS information of the first unmanned aerial vehicle, Wherein the first unmanned aerial vehicle is reset in a direction opposite to a position of the first unmanned aerial vehicle closest to the first unmanned aerial vehicle among the positions included in the information, Is reset. The method of claim 1,

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