KR100791069B1 - Geographical features monitoring system - Google Patents

Abstract

A geographical feature monitoring system is provided to monitor a geographical change according to a level change for each point in real time using a measuring unit, a terminal for collecting coordinates and angle changes, and a calculation unit. A geographical feature monitoring system includes a plurality of measuring units(10), a terminal(20), and a calculation unit(30). The measuring units include a measurement control unit(14), a wireless transmitting unit(15), an output terminal(16), a measurement control panel(17), and a fixation unit(18). The measuring units are disposed at target areas apart from each other. The terminal includes a case, a GPS(Global Positioning System) unit, a wireless receiving unit, an input terminal(24), a terminal control unit, and a terminal control panel. The calculation unit acquires a geographical change by the use of a calculation program(31) by receiving inclination angle values and coordinate data.

Description

Geographical features monitoring system using ground control point and GPS

1 is a block diagram showing a terrain surveying correction system using the ground reference point and GPS according to the present invention,

2 is a block diagram showing a terminal of a terrain surveying correction system using the ground reference point and GPS according to the present invention;

3 to 5 are reference diagrams explaining the operation of the calculation program of the terrain surveying correction system using the ground reference point and GPS according to the present invention.

<Description of the symbols for the main parts of the drawings>

10; Measuring device, 11; support fixture,

12; A housing, 13; Tilt sensor,

14; A measurement control unit 15; Wireless Transmission Unit,

16; Output terminal 17; Measuring control panel,

18; Fixture, 10a; Coupling,

20; Terminal 21; case,

22; GPS unit 23; Wireless Receiver,

24; Input terminal, 25; Terminal control unit,

26; Terminal control panel 27; Azimuth measuring device,

30; Computing device, 31; Operation program.

The present invention relates to a geospatial surveying correction system using the ground control point and the GPS to be able to monitor the terrain changes in a wide range of soft ground in real time.

In general, for large buildings such as harbors and airports, it is necessary to prepare for topographical changes such as settlement and elevation of the ground.

In this case, it is preferable to measure the change of terrain in real time. However, in the case of leveling, which is generally performed, the overall terrain is measured by measuring the relative height of another point based on each point. There is a problem that it takes a lot of time and is not enough to monitor the real-time topographical changes occurring in a wide area.

In addition, in order to calculate the amount of change of the terrain by using general level surveying, basically, the height of each point of the terrain is measured to construct basic data, and when necessary, the height of each point is measured again to measure the basic data and the new measurement. The inconvenience of having to calculate the height difference of the collected data one by one.

On the other hand, in general, when the terrain is changed, rather than causing a hole to sink into one point or convexly rising to one point, the ground of a certain area is concave or raised convexly while forming a gentle slope. Therefore, it is possible to indirectly monitor the settlement or elevation of the ground by measuring the change of the inclination angle at each point.

The present invention is to solve the above problems, an object of the present invention is to provide a terrain status measurement correction system using the ground reference point and the GPS so that it is easy to measure in real time the terrain changes occurring in a wide area as a whole.

The present invention for achieving the above object,

A support 11 fixed to the ground 1, a housing 12 rotatably mounted in the horizontal direction on the support 11, and a tilt value of the housing 12 provided in the housing 12. A tilt sensing device 13 for measuring and a memory 14a storing unique ID data for identification are provided and connected to the tilt sensing device 13 to measure the tilt value measured by the tilt sensing device 13. A measurement control unit 14 stored in 14a), a wireless transmission unit 15 connected to the measurement control unit 14 to wirelessly transmit ID data and inclination value data output from the measurement control unit 14, and the measurement control unit An output terminal 16 connected to the 14 to output ID data, a measurement control panel 17 connected to the measurement control unit 14, and a housing 12 connected to the housing 12 so that the housing 12 does not rotate. It includes a fixing device (18) for fixing and spaced apart from the area to be measured A plurality of measuring devices (10) and;

The case 21, the GPS unit 22 which is provided in the case 21 and outputs the coordinate data measured by measuring the coordinates, and the ID data output from the wireless transmission unit 15 of each measuring device 10 And a wireless receiver 23 for receiving gradient value data, an input terminal 24 connected to the output terminal 16 of the measuring device 10, the GPS unit 22, a wireless receiver 23, and an input. A terminal controller 25 having a memory 25a for storing ID data, coordinate data, and inclination value data collected through the terminal 24, and the terminal controller 25 provided inside the case 21. A terminal 20 including a terminal control panel 26 connected to the terminal;

On the basis of the coordinate data and the slope value data of each measuring device 10 collected by each measuring device 10 is equipped with a calculation program 31 for calculating the amount of change of the terrain, the terminal control unit ( 25 is connected to the communication, and receives the inclination value and the coordinate data of each measuring device 10 stored in the memory 25a of the terminal control unit 25 to calculate the change of the terrain using the calculation program 31 It includes a calculation device 30 for outputting after,

A coupling part 10a is formed on the upper surface of the housing 12 of the measuring device 10 to detachably couple the terminal 20, and the terminal 20 is coupled to the coupling part 10a on the terminal 20. There is provided a terrain surveying correction system using the ground reference point and the GPS, characterized in that the azimuth measuring device 27 for measuring the azimuth angle.

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

1 and 2, the terrain status measurement correction system using the ground reference point and GPS according to the present invention is

A plurality of measuring devices 10 arranged in a target area to be measured and measuring inclination values of respective points; A terminal 20 for collecting in real time the coordinates of each measuring device 10 and the inclination value data of each point measured by each measuring device 10; It is connected to the terminal 20 is composed of a calculation device 30 for calculating and outputting the terrain change by using the coordinates and the slope value of each measurement device 10 collected in the terminal 20.

The measuring device 10 includes a support 11 fixed to the ground 1, a housing 12 rotatably mounted in the horizontal direction on the support 11, and provided in the housing 12. A tilt sensing device 13 for measuring a tilt value of (12), and a memory 14a storing unique ID data for identification, and connected to the tilt sensing device 13 by the tilt sensing device 13; A measurement control unit 14 for storing the measured gradient value in the memory 14a, and a wireless transmission unit connected to the measurement control unit 14 to wirelessly transmit ID data and slope value data output from the measurement control unit 14; 15), an output terminal 16 connected to the measurement control unit 14 to output ID data, a measurement control panel 17 connected to the measurement control unit 14, and a housing connected to the housing 12. And a fixing device 18 for fixing the 12 to prevent rotation, Spaced apart in the area.

The support 11 is provided with a plurality of legs (11a) in the lower side, fixed to the ground (1), such as anchor bolts (11b), the terrain changes occur when the ground (1) is inclined (1) Following inclination with (1).

The housing 12 is rotatably mounted on the upper end of the support 11 via the bearing 12a and is rotated in the horizontal direction by the driving motor 19.

The inclination detecting device 13 may arrange two inclination sensors for detecting the inclination of the housing 12 in a perpendicular direction on a plane to measure the inclination of the measuring device 10 with respect to the vertical direction. At this time, the inclination sensor is configured to measure the inclination of the housing 12 by using a method such as measuring the fluid movement or metal inclination as the housing 12 is tilted. At this time, the inclination detection devices 13 provided in each measuring device 10 are all disposed to face the same direction, and in particular, the inclination detection sensor provided in the inclination detection device 13 faces in the east-west direction and the north-south direction. It is preferable to arrange.

The measurement control unit 14 outputs the ID data stored in the memory 14a and the tilt value data of the measurement device 10 measured by the tilt detection device 13 through the wireless transmitter 15 at a predetermined time. Do it. The output terminal 16 is connected to the input terminal 24 of the terminal 20 to be described later, and serves to transmit the ID data to the terminal 20.
In this case, the ID data stored in the memory 14a of each measuring device 10 are set differently, and when the inclination value data measured by each measuring device 10 is transmitted to the terminal 20, the ID data is transmitted together. Thus, it is configured to identify from which measuring apparatus 10 the gradient value data received at the terminal 20 is transmitted.

The measurement control panel 17 is provided on the upper surface of the housing 12 so that the user operates the measurement control panel 17 to turn the measurement device 10 on or off, or various commands to the measurement control unit 14. It is configured to allow input.

The fixing device 18 is provided at one side of the housing 12, so that the user can rotate the handle 18a to fix or release the housing 12 from being rotated.

In addition, one side of the measuring device 10 is formed with a coupling portion 10a to which the terminal 20 is detachably coupled. The coupling part 10a is provided at one side of the upper surface of the housing 12, so that the user can operate the terminal 20 and the measuring device 10 in a state in which the terminal 20 is coupled to the coupling part 10a. The output terminal 16 is provided on one side of the coupling unit 10a, and when the terminal 20 is coupled to the coupling unit 10a, the output terminal 16 and the input terminal 24 of the terminal 20 are provided. ) Are automatically configured to be interconnected.

At this time, the measurement control unit 14, after the user fixed the measurement device 10 to the ground (1), by using the control panel, the tilt measuring device 10 to control the first measurement device 10 After measuring the inclination of the, and transmits it to the terminal 20 as a basic measurement value, it is repeatedly measured at a predetermined time and transmitted to the terminal 20.

In addition, the terminal 20 includes a case 21, a GPS unit 22 provided in the case 21 and outputting coordinate data measured by measuring coordinates, and a wireless transmitting unit of each measuring device 10. The wireless receiver 23 for receiving the ID data and the slope value data outputted from (15), an input terminal 24 connected to the output terminal 16 of the measuring device 10, and the GPS unit 22 And a terminal controller 25 having a memory 25a storing ID data, coordinate data, and inclination value data collected through the wireless receiver 23 and the input terminal 24, and connected to the terminal controller 25. A terminal control panel 26 and the azimuth angle measuring device 27 provided in the case 21 to measure the azimuth angle of the terminal 20.

The case 21 is composed of a box of synthetic resin material detachably coupled to the coupling portion 10a of the measuring device 10, and configured to protect each component mounted therein.

The GPS unit 22 measures the current position by measuring a relative position of the satellite floating on a known orbit, and the terminal 20 is coupled to the coupling unit 10a of the measuring device 10. In this state, the current position of the terminal 20 is measured to indirectly measure the position of the measuring device 10, and outputs coordinate data of the measured position to the terminal controller 25. At this time, the coordinate data measured by the GPS indicates the horizontal position of each measuring device 10, and does not include data indicating the position or altitude in the vertical direction.

The input terminal 24 is provided to be exposed to the outer surface of the case 21, when the terminal 20 is fixed to the coupling portion 10a of the measuring device 10, the input terminal 24 is measured device ( It is connected to the output terminal 16 of 10), and transmits the ID data output from the output terminal 16 to the terminal control unit 25.

The terminal controller 25 converts the ID data, coordinate data, and inclination value data of each measuring device 10 collected through the input terminal 24 and the receiving device into a DB and stores the stored data in the memory 25a. It transmits to the computing device 30. In addition, since the terminal controller 25 of the measuring device 10 continuously transmits the ID data and the slope value data of the measuring device 10 through the transmitting device, the terminal controller 25 has an input terminal 24. Through continuously updating the inclination value of each measuring device 10. At this time, each measurement device 10 transmits the slope value data and the ID data together, the terminal controller 25 analyzes the received ID data to determine which measurement device 10 is received from the received slope value data By confirming, the slope value data of the corresponding measurement value can be updated.

The azimuth measuring device 27 measures the azimuth of the terminal 20 in a state in which the user couples the terminal 20 to the coupling unit 10a of the measuring device 10, thereby indirectly measuring the housing ( 12) and the direction in which the tilt detection device 13 provided in the housing 12 is directed, the user rotates the housing 12 to determine the direction in which the azimuth measuring device 27 is determined (in this embodiment, north-west, north-west) Direction), an alarm sound or the like is output to indicate that the housing 12 is directed in the correct direction.

The computing device 30 is equipped with a computing program 31, using a computer that is communicatively connected to the terminal (20). In this case, the arithmetic unit 30 and the terminal 20 are provided with a USB port, respectively, so that the arithmetic unit 30 can be connected to the terminal control unit 25 of the terminal 20 via a USB line.

The calculation program 31 functions to calculate the amount of change of the terrain based on the coordinate data and the slope value data of each measuring device 10.

3 to 5 illustrate the operation of such a calculation program 31, which illustrates a terrain change calculation method when the ground 1 causes a terrain change in a planar state.

As shown in FIG. 3A, after distributing and installing a plurality of measuring devices 10 on the ground 1 in a planar state, the coordinates of each measuring device 10 collected by the terminal 20 are distributed. When the data and the slope value data are stored in the computing device 30, the computing program 31 shows virtual points a to e at the intermediate positions of the respective measuring devices 10, as shown in Fig. 4A. Is set to calculate the horizontal distance from the measuring device 10 to the virtual point.

And, as shown in (b) of FIG. 3, when the slope value of each measuring device 10 changes as the terrain 1 is inclined and the ground 1 is inclined, the calculation program 31 is shown in (b) of FIG. As shown, the height change h1, h2 between each measuring device 10 and the virtual point is calculated using a triangulation method, and as shown in (c) of FIG. 4, the measuring device is equal to the height change value of the virtual point. Change the top and bottom height (h1 + h2) of (10), and measure the topographical change of the entire area using the changed height change of the measuring device 10, and outputs to the monitor or printer. The terrain change value measured using the height change of each point calculated as described above is represented by the dotted line (deformed topographical form calculated by the calculation program 31) and solid line (deformation form of the actual terrain) of FIG. 5. However, there is a slight error and it is almost similar. At this time, by narrowing the interval of each measuring device 10, it is possible to further reduce the error.

In this way, by measuring the topographical change in the X-axis direction and the Y-axis direction, the three-dimensional topographical change can be measured.

On the other hand, when measuring the topographical change of the curved surface rather than the plane, the calculation program 31 uses the above-described method, not the actual shape of the ground (1), but the height of each part of the ground (1) Only change is measured. That is, the calculation program 31 does not measure the actual bending state of the ground 1, but when the program 31 is operated, the heights of the points where the respective measuring devices 10 are installed are the same. After modeling and setting the state of the ground, only the change of the height of each point of the ground (1) is measured, and when the topographic change of the ground (1) occurs, the point according to the topographical change, not the actual deformation of the ground (1) Only the amount of deformation of the ground 1 is calculated based on the amount of change in height, and only the amount of topographical change according to the amount of change is output.

The operation of the geospatial survey correction system configured as described above is as follows.

First, the user distributedly arranges and fixes a plurality of measuring devices 10 in an area to measure the terrain change, and combines the terminal 20 with the coupling part 10a of the measuring device 10, and then the azimuth measuring device ( The housing 12 is rotated in accordance with the signal of 27 to direct the azimuth measuring device 27 toward a predetermined direction (in the present embodiment, north-west, north-south direction), and then the housing 12 using the fixing device 18. Fix it so that it does not rotate.

Then, when the user operates the measurement control panel 17 of the measurement device 10 to turn on the measurement device 10, the measurement device 10 is a measurement device through the wireless transmission unit 15 and the output terminal 16. (10) outputs the ID data and the slope value data, the terminal 20 is the ID data output through the output terminal 16 of the measuring device 10, the coordinate data output from the GPS unit 22, and In addition, the inclination value data transmitted through the transmission device of the measuring device 10 is received and stored in the DB of the memory 25a for each ID of each measuring device 10. At this time, the terminal 20 by measuring the coordinates using the GPS unit 22 in the state coupled to the coupling portion 10a of the measuring device 10, the terminal 20 of the measuring device 10 is coupled Coordinates are measured indirectly.

In addition, the user connects the terminals 20 to all the measuring apparatuses 10 in order, collects the coordinate data and the inclination value data for each ID of the measuring apparatus 10, and then uses the terminal 20 for the computing apparatus 30. When connected to, the calculation device 30 receives the coordinate data and the slope value data of each measuring device 10 stored in the DB of the terminal 20, the coordinate value and the slope value of the point where each measuring device 10 is installed Set as reference value and save first.

Then, when ID data and inclination value data are continuously transmitted from each measuring device 10, the terminal 20 receives this, updates the inclination value data of each measuring device 10, and inclines the measuring device 10. When a change occurs in the value data, the calculation device 30 calculates the height change of the point where the measurement device 10 is installed by using the calculation program 31 and outputs the numerical value or graph through a monitor or a printer.

Therefore, the user can check the height change of each point and the corresponding terrain change in real time through the outputted data.

The terrain status measurement correction system configured as described above measures the change of the slope of each point and measures the overall terrain change by using the indirect leveling method using triangulation, so that the terrain change is monitored in real time even in a large area. There is an advantage to this.

In addition, the terminal 20 is provided with a variety of equipment intensively, since the measuring device 10 is provided with only a simple equipment, including the tilt measuring device 10, there is an advantage that the cost is low.

In addition, in order to calculate the amount of terrain change at each point in the prior art, the height change of the height of each point of the actual terrain must be calculated from the reference data, while the terrain status measurement correction system according to the present invention It is very convenient because it can measure the amount of change of height directly and output it as graphic or numerical value.

As described above, the terrain surveying correction system according to the present invention has a plurality of measuring devices 10 which are distributed at each point and measure the change of angle of the ground 1, and the coordinate and angle change amount of each measuring device 10. And a point 20 using the coordinate data and the angle change amount data of each measuring device 10 collected in the terminal 20 by connecting the terminal 20 to the terminal 20 and a calculation program 31 mounted thereon. Comprised of arithmetic unit 30 for measuring the change in height, it is possible to monitor the change in the terrain according to the height change of each point in real time, there is an advantage that is very convenient to use.

Claims (1)

A support 11 fixed to the ground 1, a housing 12 rotatably mounted in the horizontal direction on the support 11, and a tilt value of the housing 12 provided in the housing 12. A tilt sensing device 13 for measuring and a memory 14a storing unique ID data for identification are provided and connected to the tilt sensing device 13 to measure the tilt value measured by the tilt sensing device 13. A measurement control unit 14 stored in 14a), a wireless transmission unit 15 connected to the measurement control unit 14 to wirelessly transmit ID data and inclination value data output from the measurement control unit 14, and the measurement control unit An output terminal 16 connected to the 14 to output ID data, a measurement control panel 17 connected to the measurement control unit 14, and a housing 12 connected to the housing 12 so that the housing 12 does not rotate. It includes a fixing device (18) for fixing and spaced apart from the area to be measured A plurality of measuring devices (10) and; The case 21, the GPS unit 22 which is provided in the case 21 and outputs the coordinate data measured by measuring the coordinates, and the ID data output from the wireless transmission unit 15 of each measuring device 10 And a wireless receiver 23 for receiving gradient value data, an input terminal 24 connected to the output terminal 16 of the measuring device 10, the GPS unit 22, a wireless receiver 23, and an input. A terminal controller 25 having a memory 25a for storing ID data, coordinate data, and inclination value data collected through the terminal 24, and the terminal controller 25 provided inside the case 21. A terminal 20 including a terminal control panel 26 connected to the terminal; On the basis of the coordinate data and the slope value data of each measuring device 10 collected by each measuring device 10 is equipped with a calculation program 31 for calculating the amount of change of the terrain, the terminal control unit ( 25 is connected to the communication, and receives the inclination value and the coordinate data of each measuring device 10 stored in the memory 25a of the terminal control unit 25 to calculate the change of the terrain using the calculation program 31 It includes a calculation device 30 for outputting after, A coupling part 10a is formed on the upper surface of the housing 12 of the measuring device 10 to detachably couple the terminal 20, and the terminal 20 is coupled to the coupling part 10a on the terminal 20. Terrain status surveying correction system using the ground reference point and the GPS, characterized in that the azimuth measuring device for measuring the azimuth angle is provided.

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