KR101476638B1

KR101476638B1 - A drawing data system for collecting geographical information with connecting leveling device

Info

Publication number: KR101476638B1
Application number: KR1020140110736A
Authority: KR
Inventors: 정규태
Original assignee: (주)대지이엔지
Priority date: 2014-08-25
Filing date: 2014-08-25
Publication date: 2014-12-26

Abstract

An embodiment of the present invention relates to a geodetic survey data system collecting geographical information by leveling device connection. According to the present invention, underground-buried geodetic survey assistance equipment including a tripod function is installed in the vicinity of a national leveling point located at a high-level ground and used frequently statistically so that a geodetic survey operator can move a total station or only a staff if necessary to a high-level ground position and perform accurate geodetic survey based on the national leveling point. The embodiment of the present invention includes a buried housing, a separate housing, a smart elevatable cylinder, a support plate, a total station, a self power generation device, a power supply connector, a cylinder power connector, a total station power connector, a signal receiving unit, a storage unit, a control unit, a wireless communication module, a national leveling point use status integrated management server, a user smart terminal, and a map information management device.

Description

[0002] A geodetic surveying system for collecting geographical information using level instrument connections is known as a geodetic surveying system,

The present invention relates to a geodetic surveying data system for collecting geographic information in a level instrument connection in the field of geodetic surveying. More particularly, the present invention relates to a geodetic surveying data system, A geodetic survey helper is installed so that the operator of the geodetic survey can move the total station and, if necessary, the staff to the corresponding position in the highland, and then perform a more accurate geodetric survey based on the national level point. To a geodetic surveying data system for collecting geographic information by means of a connection.

Generally, in order to produce and correct the digital map used in GIS, aerial photographing of a certain area, aerial photographing obtained through aerial photographing, and aerial photographing information are produced.

Then, the digital map is produced through the above-described process, and then the aerial photographing is performed again at regular intervals to newly create the aerial photographing information, thereby correcting or updating the digital map based on the existing aerial photographing information.

In this case, if there is an error between the coordinate of the existing digital map or the coordinate of the artificial structure and the coordinates of the newly created aerial photographing information or the recorded land feature or the artificial structure, Or it was difficult to judge whether there is an error in the newly created aerial photographing information.

Therefore, the point where the error occurs should be measured and the error should be corrected. Usually, the total station is used to accurately position the measurement point.

The total station will be briefly described as a total station in which an electronic cedar lamp (Electronic Theodolite) and an Electro-Optical Instruments (EDM) are integrated into one device. The total station is divided into four components: a vertical angle detector for measuring the vertical angle caused by the vertical movement of the telescope; a horizontal angle detector for measuring the horizontal angle caused by the rotation of the body in the left and right directions; A distance measuring part, and a tilting sensor for measuring and correcting the horizontal of the main body.

When collecting the geographical information through the total station, the geodetic surveying work is performed based on the coordinates of the national level point.

A brief description of national level points is that the national level point is the basis of the vertical position, and the elevation of the national level point is measured by direct level measurement along the route based on the level origin. These national level points are divided into first and second level points buried along the first level route and the second level level buried along the second level route, and the grade of the national level point corresponds directly with the accuracy of the measured value.

To illustrate the use of national level points, a business executing company in a specific area will receive and use the national level point scorecard which records the national level point location of the business execution region from the Geographical Information Service to use the national level point.

However, the above-mentioned national level point can not be installed only considering the convenience of the worker who performs the geodetic surveying operation, and the area where the error between the existing digital map and the newly created aerial photographing information is also limited to the area where the geodetic surveying work is easy It can not be said that a considerable number of national level points are installed in the highlands such as mountainous terrain, and at the same time, geodetic surveys are based on the national level points of these highlands.

Therefore, it is difficult for the operator of the geodetic surveying to move the total station and the tripod surveying equipments to the vicinity of the national level located in the highlands, and the worker who consumes the physical power for the transfer of the surveying equipment, . In addition, it is unreasonable to maintain the tripod level horizontally due to rough terrain in mountainous terrain, which, as mentioned above, comes with a greater burden on the part of the physically exhausted operator.

In addition, among the national level points located in the highlands, there will be a national level in which the geodetic survey is frequent based on the statistical information of the national level points frequently used for collecting the surrounding geographical information. If you use it as a necessary data for surveying, it will help you to do more efficient geodetic surveying.

Korea Patent Registration No. 10-1249913 (Mar. 23, 2013) "Geodetic data-only system for level-instrument connection for geographic information collection" Korea Patent Registration No. 10-1116190 (2012.02.07.) "Geodetic data management system through level instrument for terrain information collection"

An embodiment of the present invention is to install an underground buried geodetic surveying support facility including a tripod function near a national level point which is located at a high altitude and which is frequently used statistically, To a geographical surveying data system that collects geographical information through a level meter connection, which enables more precise geodetic surveying based on the national level point.

In addition, the embodiment of the present invention can be applied to an underground burial-type system in which major components are movable near a national level point located at a high altitude and frequently used statistically, so that a worker of a geodetic surveying moves most equipment required for the geodetic survey The geodetic surveying assistance facility is provided to make it available immediately at the geodetic surveying site. At the same time, it is decided whether or not the geodetic surveying assistance facility is always available according to the frequency of use of the national level point. Provides a geodetic survey data system that collects geographical information through level instrument connections that enable efficient management.

A geodetic surveying data system for collecting geographical information with a level meter connection according to an embodiment of the present invention includes a main body buried in the ground adjacent to a national level point, A cover for opening and closing the receiving space inside the main body through rotation, and a light emitting unit having a cover for visual confirmation from the outside and a wireless communication unit for receiving an external operation signal, A separating housing coupled to the receiving space of the separating housing so as to be detachably received and detachably coupled to the separating housing and capable of being separated and moved from the embedding housing as required; A smart up / down cylinder reciprocating in a vertical direction, The cylinder rod is coupled to the cylinder rod front end and moves up and down according to the upward and downward movement of the cylinder rod. The cylinder rod is lifted up or raised to a predetermined height from the ground for embedding the buried enclosure, And a support portion corresponding to the fixed portion of the support plate, and is detachably coupled to the upper surface of the support plate through a coupling between the support portion and the support portions of the support plate, A total station including a first connecting part for supplying power from the outside and a second connecting part for receiving various data and electrical signals from the outside, and a total station installed on the ground adjacent to the buried enclosure, A first power generation device including a solar cell for switching to A second power generation device that generates electricity using wind speeds generated in the vicinity of the first power generation device and the second power generation device, and a second power generation device that is connected in parallel to the first power generation device and the second power generation device, And a first power supply line which is electrically connected to a rechargeable battery of the self-power generating apparatus and extends to a space inside the main body of the embedding medium, a power supply connector And a power supply unit electrically connected to a power supply unit of the smart ascending and descending cylinder and electrically connected to a front end of a power supply line extending to an outer side of the separating enclosure to supply power to the smart ascending and descending cylinder through electrical connection with the power supply connector A battery power supply connector for supplying electricity to the battery of the self-power generation apparatus; A total station power connector installed on the support plate via a second power supply line extending to the support plate and supplying power to the total station through an electrical connection with the first connection part of the total station, A signal receiver mounted on the support plate and electrically connected to the second connection unit of the total station to receive measurement data and a variety of data processed by the total station during the geodetection of the total station, A storage unit for storing data received through a receiver and various other data; and a storage unit for storing information on the information received each time a signal is received from the signal receiver, Identification code A control unit for generating the national level point utilization information by generating the national level point utilization information and outputting the generated national level point utilization information and storing the signals received from the signal reception unit in the storage unit; And a server for receiving the national level point information transmitted through the wireless communication module through the communication network and transmitting the unique ID code for each country level point and the national level point information transmitted from the controller, And an application for geodetic surveying for operating the light up / down operation of the light emitting unit and the operation of the smart up / down cylinder, Remote control function for remotely controlling the descending cylinder A geographical information DB for storing geographical information corresponding to the geographical information, a geographical information DB for storing geographical information corresponding to the geographical information, geographical information including geographical survey data based on national geographical data transmitted from the total station, The geographical information DB may include a collection information comparison module for comparing the geographical information DB with the existing geographical information previously stored in the geographical information DB, And a digital map output module for synthesizing geographical information stored in the geographical information DB and geographical information stored in the geographical information DB and outputting a digital map in a completed form, do.

According to the embodiment of the present invention, an underground burial type geodetic surveying support facility including a tripod function is installed near a national level point located at a high altitude and statistically frequently used, whereby an operator of a geodetic surveying system It is possible to perform more precise geodetic surveying based on the national level point after moving the statue only to the corresponding position in the highland.

In addition, it is installed in an underground buried type with the main components being movable near the national level point, which is located at the high altitude and frequently used statistically, so that the worker of the geodetic surveying does not move most of the equipment required for the geodetic survey, It provides the geodetic surveying help facility that can be used immediately, and at the same time, it determines whether the geodetic surveying assistance facility is always available according to the frequency of use of the national level point, .

1 is a block diagram conceptually illustrating a geodetic survey data system for collecting geographic information in a level meter connection according to an embodiment of the present invention;
2 is a block diagram illustrating the overall configuration of a geodetic survey data system for collecting geographic information with a level meter connection in accordance with an embodiment of the present invention.
Figures 3 and 4 are cross-sectional views of structures and operating conditions of a recess in a geodetic survey data system for collecting geographic information with a level meter connection according to an embodiment of the present invention;
FIG. 5 is a diagram illustrating a state-of-the-art point-of-use management screen of a national level point-of-use integrated management server in a geodesic survey data system for collecting geographic information by level instrument connection according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components within each described embodiment may be varied without departing from the spirit and scope of the present invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

Whenever a component is referred to as " including " an element throughout the specification, it is to be understood that the component may include other elements, not the exclusion of any other element, unless the context clearly dictates otherwise. Also, the terms " part, " " module, " and the like, which are described in the specification, refer to a unit for processing at least one function or operation, and may be implemented by hardware or software or by a combination of hardware and software .

1 to 5, a geodetic survey data system for collecting geographic information with a level meter connection according to an embodiment of the present invention will be described.

1 is a block diagram conceptually illustrating a geodetic survey data system for collecting geographic information with a level meter connection according to an embodiment of the present invention.

As shown, a geodetic survey data system for collecting geographic information in a level meter connection according to an embodiment of the present invention includes a support facility S for geodetic survey of the total station near a national level point A located in a high elevation, And at the same time, the help facility S transmits usage fact information of the country level point A to the remote country level point utilization state integrated management server 600 via the communication network every time when the assistive facility S is used in conjunction with the total station .

Accordingly, the national level point utilization integrated management server 600 calculates the national level point (A) of the highland according to the utilization fact information of the corresponding national level point (A) transmitted from the geodetic survey assistance facility (S) The main constituent of the geodetic surveying assistance facility S can be configured in a movable form so that the main constitution of the movable geodetic surveying assistance facility S can be described in detail National Level Point of Use According to the usage status of the integrated management server 600 according to the highland nation level point (A), it can be installed efficiently at the national level point (A), which is frequently used.

The following is a detailed description of a geodetic survey data system for collecting geographic information with a level meter connection according to an embodiment of the present invention, with reference to FIGS. 2-4.

2 is a block diagram illustrating the overall configuration of a geodetic survey data system for collecting geographic information in a level meter connection in accordance with an embodiment of the present invention. 3 and 4 are cross-sectional views showing structures and operating states of a recess in a geodetic survey data system for collecting geographical information with a level meter connection according to an embodiment of the present invention.

As shown, a geodetic survey data system for collecting geographic information in a level meter connection according to an embodiment of the present invention includes a buried enclosure 210, an isolation enclosure 220, a smart ascending / descending cylinder 240, a support plate 230, a total station 100, an electric power generating device 300, a power supply connector 350, a cylinder power connector 243, a total station power connector 231, a signal receiving section 232, a storage section 260, A control unit 250, a wireless communication module 270, a nationwide point-of-use integrated management server 600, a user smart terminal 400, and a map information management device 500.

The buried enclosure 210 includes a main body 211, a cover 212, and a light emitting portion 214.

The main body 211 is embedded in the ground adjacent to the national level point A and the cover 212 is coupled to the upper end of the main body 211 such that the main body 211 can be rotated by 180 degrees or more, And opens and closes the inside accommodating space 211a. That is, the cover 212 is coupled to the upper end of the main body 211 through a hinge coupling portion 213 allowing rotation of 180 ° or more, and opens or closes the accommodation space 211a of the main body 211. The light emitting unit 214 is installed on the cover 212 in a state where it can be visually confirmed from the outside. The light emitting unit 214 includes a wireless communication unit (not shown) for receiving an external operation signal.

The light emitting unit 214 is turned on / off via a control signal transmitted from the user smart terminal 400 and the light emitting unit 214 is also connected to the user smart terminal 400 via a wireless transmission (Not shown) for receiving a control signal to be transmitted to the mobile communication terminal.

The separation housing 220 is detachably coupled to the housing space 211a of the body 211 so that the separation housing 220 can be detachably coupled to the housing 211 of the body 211, The separate enclosure 220 is detachably coupled to the inside of the main body 211 of the other embedding enclosure 210 by being detached and moved from the corresponding embedding enclosure 210 if necessary, .

Although the separating housing 220 is detachably coupled to the embedding housing 210 through the tightening coupling bolt 215 in the present embodiment, the present invention is not limited thereto, Various coupling structures may be used within a range that is detachably coupled to the inside of the accommodating space 211a of the embedding housing 210 so as to be detachable if necessary and moved to another embedding housing 210 to be detachably coupled .

In this embodiment, at least one bolt coupling hole is formed on the inner surface of the body 211 of the embedment body 210, and a bolt insertion hole corresponding to the bolt coupling hole of the embedding body 210 is formed in the separation body 220. [ And the tightening coupling bolt 215 is coupled to the bolt coupling hole of the buried enclosure 210 through the bolt insertion hole of the separation box body 220 and the head portion thereof is closely attached to the periphery of the bolt insertion hole 220 Is detachably coupled to the inside of the main body 211 of the embedding housing 210.

The smart lifting and lowering cylinder 240 is installed upright in a state of fixing the lower end to the inner bottom surface of the separating housing 220 so that the smart lifting and lowering cylinder 240 has a structure in which the cylinder rod 241 reciprocates in the vertical direction .

The support plate 230 is coupled to the tip of the cylinder rod 241 of the smart lifting cylinder 240 and moves up and down in association with the upward and downward movement of the cylinder rod 241. The support plate 230 is lifted up and down from the ground, And is housed inside the separating housing 220 again at the elevated position. The support plate 230 is provided with a fixing portion 233 for fixing an object to be supported on the upper surface thereof. In other words, the upper surface of the support plate 230 is provided with the fixing portion 233 corresponding to the fixing portion 130 of the total station 100 to be described later, so that the fixing portion 233 of the supporting plate 230, The total station 100 is detachably supported on the upper surface of the support plate 230 through the fixing portion 130 of the station 100. [

The total station 100 has a support 130 corresponding to the fixing portion 233 of the support plate 230 as described in the above description of the support plate 230, The total station 100 is detachably coupled to the upper surface of the support plate 230 through the support plate 230. The total station 100 includes a first connection unit 110 for supplying power from the outside and a second connection unit 120 for receiving various data and electrical signals from the outside, Is the same as that of the conventional total station used for the conventional geodetic surveying, and thus the description of the detailed configuration of the total station 100 in this embodiment is omitted.

The self-power generation apparatus 300 is installed on the ground adjacent to the buried enclosure 210. The self-power generation apparatus 300 includes a first power generation apparatus 310 including a solar cell for converting sunlight into electric energy, And a second power generation device 320 that generates power using a wind speed generated in the vicinity of the position. The self power generation apparatus 300 is also connected to the first power generation apparatus 310 and the second power generation apparatus 320 in parallel to charge the electric energy generated by the first power generation apparatus 310 and the second power generation apparatus 320, And a rechargeable battery 330 for discharging the rechargeable battery.

The power supply connector 350 is electrically connected to the rechargeable battery 330 of the self-power generation apparatus 300 and includes a first power supply line 340 extending to the inner accommodating space 211a of the main body 211 of the embedment enclosure 210, And is installed in the accommodating space 211a inside the main body 211 through the intermediary of the main body 211. [ In this embodiment, the power supply connector 350 is in the form of a plug used in ordinary electronic equipment, but the present invention is not limited thereto.

The cylinder power connector 243 is electrically connected to the power supply of the smart up / down cylinder 240 and electrically connected to the tip of the power supply line 242 which can extend to the outside of the separation enclosure 220. That is, the cylinder power connector 243 functions to supply power to the smart up / down cylinder 240 through electrical connection with the power supply connector 350. In this embodiment, since the power supply connector 350 is of a plug type, the cylinder power connector 243 is an outlet, but the present invention is not limited thereto.

The total station power supply connector 231 is electrically connected to the rechargeable battery 330 of the self power generation apparatus 300 and is installed on the support plate 230 via the second power supply line 234 extending to the support plate 230 do. The total station power supply connector 231 functions to supply electric power to the total station 100 through electrical connection with the first connection unit 110 of the total station 100.

The signal receiving unit 232 is installed on the support plate 230. The signal receiving unit 232 is electrically connected to the second connection unit 120 of the total station 100 to measure the measurement values of the total station 100, And various data processed in the total station 100.

The storage unit 260 is installed on the support plate 230. The storage unit 260 is installed to store data received through the signal receiving unit 232 and various other data.

The control unit 250 is installed on the support plate 230. The control unit 250 controls the information received each time a signal is received from the signal receiving unit 232, ) To generate country level point utilization information. The control unit 250 outputs the generated national level point information to the wireless communication module 270 and the control unit 250 stores the signals received from the signal receiving unit 232 in the storage unit 260.

The wireless communication module 270 transmits the national level point information output from the controller 250 to an external server, that is, the national level point of use integrated management server 600 via the communication network.

The national level point utilization integrated management server 600 receives the national level point utilization information transmitted through the wireless communication module 270 via the communication network, Code and the national level point information generated and transmitted by the controller 250 are mapped and stored in the form of a table.

5, FIG. 5 illustrates an example of the national level point usage management management screen in the national level point utilization status integrated management server 600. As shown in FIG. 5, the total number of national point points The cumulative number of times of use, the cumulative number of times of use during a recent period, and the date and time of use during a recent period are mapped with the corresponding national level points and stored.

2 to 4, the user smart terminal 400 includes a geodetic surveying application for on / off operation of the light emitting portion 214 of the buried enclosure 210 and operation operation of the smart ascending / descending cylinder 240 (410) is mounted. The user smart terminal 400 functions as a remote controller for remotely adjusting the light emitting unit 214 and the smart lifting cylinder 240 of the buried enclosure 210 through execution of the geodetic measurement dedicated application 410. [ In this embodiment, the user smart terminal 400 includes the touch screen 420 and the touch panel 420 is connected to the light emitting portion 214 of the embedding housing 210 and the smart lifting / lowering cylinder 240 The input of the operation signal is described as an example, but the present invention is not limited thereto.

Lastly, the map information management apparatus 500 includes a terrain information DB 510, a geographic information DB 520, a collected information comparison module 530, an update module 540, and a digital map output module 550 .

The terrain information DB 510 stores imaged terrain information, and the geographic information DB 520 stores geographic information, which is numerical information corresponding to the terrain information.

The collected information comparison module 530 compares the geographical information including the geographical survey data based on the national level point A transmitted from the total station 100 with the existing geographical information previously stored in the geographical information DB 520.

The update module 540 corrects and updates the geographical information of the geographical information DB 520 based on the geographical information transmitted from the total station 100 when the comparison result of the collected information comparison module 530 exceeds a reference value.

The digital map output module 550 synthesizes the terrain information stored in the terrain information DB 510 and the geographical information stored in the geographical information DB 520 to output a digital map.

1 to 5, the geodetic survey data system for collecting geographical information with the level meter connection according to the present invention is a geodetic surveying data system for collecting geographical information in the vicinity of a national level point, which is located at a high place and is frequently used statistically, And a geodetic surveying facility is installed to allow the operator of the geodetic surveying to move the total station and only the staff as needed to the corresponding position in the highland, and then perform a more accurate geodetical survey based on the national level point I can do it.

In addition, it is installed in an underground buried type with the main components being movable near the national level point, which is located at the high altitude and frequently used statistically, so that the worker of the geodetic surveying does not move most of the equipment required for the geodetic survey, It provides the geodetic surveying help facility that can be used immediately, and at the same time, it determines whether the geodetic surveying assistance facility is always available according to the frequency of use of the national level point, I will.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. 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 as defined by the appended claims.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described above, and all of the equivalents or equivalents of the claims, as well as the claims, will be included in the scope of the present invention.

100: total station 110: first connection
120: second connection part 130:
210: an embedding body 211:
211a: accommodation space 212: cover
213: hinge connecting part 214:
215: Fastening coupling bolt 220: Separate housing
230: support plate 231: total station power connector
232: Signal receiving section 233:
234: second power supply line 240: smart up / down cylinder
241: cylinder rod 242: power line
243: Cylinder power connector 250:
260: storage unit 270: wireless communication module
300: self-power generation device 310: first power generation device
320: second generator 330: rechargeable battery
340: first power supply line 350: power supply connector
400: user smart terminal 410: dedicated application for geodetic surveying
420: touch screen 500: map information management device
510: terrain information DB 520: geographic information DB
530: collected information comparison module 540: update module
550: Digital map output module
600: National Level Point Utilization Integrated Management Server

Claims

And a cover for opening and closing the receiving space inside the main body through the rotation so as to be rotatable by 180 degrees or more on the top of the main body, And a light emitting unit provided with a wireless communication unit for receiving an external operation signal, the at least one bolt coupling hole being formed on an inner surface of the body;
A separating housing which is detachably coupled to the receiving space of the main body so as to be detachable and detachable from the embedding housing as necessary and in which a bolt insertion hole corresponding to the bolt coupling hole is formed;
The bolt insertion hole of the separate enclosure is coupled to the bolt coupling hole of the buried enclosure and the head of the bolt is closely attached to the periphery of the bolt insertion hole to be detachably coupled to the inside of the body of the embedment enclosure Coupling bolts;
A smart ascending / descending cylinder installed upright in a state of fixing a lower end to an inner bottom surface of the separating housing, the cylinder rod being reciprocated in a vertical direction;
The lifting / lowering cylinder is coupled to a cylinder rod end of the smart lifting cylinder. The lifting / lowering cylinder moves up and down according to the upward / downward movement of the cylinder rod. A support plate having a fixing portion for fixing an object to be supported on an upper surface thereof;
And a support portion corresponding to the fixed portion of the support plate and detachably coupled to the upper surface of the support plate through engagement between the support portion and the support portions of the support plate, A total station comprising a second connection for receiving various data and electrical signals;
A first power generation device installed on a ground adjacent to the buried enclosure and including a solar cell for converting sunlight into electric energy, a second power generation device generating electricity using a wind speed generated in the vicinity of the installation location, And a rechargeable battery connected in parallel to the apparatus and the second generator to charge electric energy generated by the first generator and the second generator, respectively;
A power supply connector electrically connected to a rechargeable battery of the self-power generating apparatus and installed in a space inside the main body through a first power supply line extending to a space inside the main body of the embedment body;
A smart lifting / lowering cylinder electrically connected to a power supply part of the smart lifting / lowering cylinder and electrically connected to a front end of a power supply line extending to the outside of the separating housing and supplying power to the smart lifting / lowering cylinder through electrical connection with the power supply connector Cylinder power connector;
A power supply line electrically connected to a rechargeable battery of the self-power generation apparatus and connected to the support plate through a second power supply line extending to the support plate, and powering the total station through an electrical connection with the first connection unit of the total station Total station power connector supplied;
A signal receiving unit installed on the support plate and electrically connected to the second connection unit of the total station to receive various data processed by the total station and measurement values at the time of the geodetection of the total station;
A storage unit installed in the support plate and storing data and various other data received through the signal receiver;
And a control unit which is installed on the support plate and synchronizes the real time information of the country level point and the unique identification code of the country level point to the information received each time the signal is received from the signal receiver, And storing the signals received from the signal receiving unit in the storage unit;
A wireless communication module for transmitting the country level point information output from the controller to an external server via a communication network;
Receiving a national level point-of-use information transmitted through the wireless communication module through the communication network, mapping a unique identification code for each country level point and national level point information transmitted from the controller, and storing the national level point- Status integrated management server;
A user smart terminal mounted with a dedicated geodetic surveying application for on / off operation of the light emitting portion of the embedment housing and an operating operation of the smart ascending / descending cylinder to remotely control the light emitting portion and the smart ascending / descending cylinder;
A geographical information DB storing numerical information corresponding to the geographical information, and a geographical information DB storing geographical information including geodetic survey data based on the national level point transmitted from the total station, And a geographical information database for storing the geographical information of the geographical information DB based on the geographical information transmitted from the total station when a difference between the comparison information of the collected information comparison module and the reference value exceeds the reference value, And a numerical map output module for synthesizing the geographical information stored in the geographical information DB and the geographical information stored in the geographical information DB to complete and output the digital map, Geodetic surveying data system that collects geographic information by connection.