KR101019674B1 - Survey Indicator Radio-Frequency Indicator - Google Patents

Abstract

The present invention relates to an electronic indicator which is embedded together in an existing buried surveying reference point and stores measurement information. The disk-shaped body 100 has a disk shape as a whole and a hollow 140 penetrating the upper and lower parts of the center; An RFID tag 200 installed inside the disc-shaped body 100 and storing and storing survey information; An antenna 300 connected to the RFID tag 200 and installed in an annular shape along the inside of the disc-shaped body 100; And a plurality of fixing pins 130 protruding toward the ground from the lower surface of the disc-shaped body 100. The survey information stored in the RFID tag 200 is read by the RFID reader 22. And, it relates to a measurement reference point electronic marker, characterized in that installed on the ground so that the existing buried measurement reference point 11 is located in the hollow 140.

Disc body, fixed pin, RFID tag, RFID reader, photovoltaic module, storage battery 700, LED, beep generator

Description

Survey Indicator Radio-Frequency Indicator

The present invention is embedded with an existing buried surveying reference point, RFID reader (or RFID electronic tag) to which the survey information (latitude, longitude, reference point type, and serial number) of the surveying reference point is built-in RFID reader easy to carry The present invention relates to an electronic marker capable of obtaining survey information directly from the field using a RFID reader.

In general, in performing survey work such as cadastral survey or civil survey, it is necessary to use a reference point that is the basis of the work in order to obtain accurate survey results. ) Is buried underground and surveyed using it.

As such, the starting point of a surveying operation using a conventional survey reference point is the positioning of a survey reference point in a survey area. In the actual survey work, the coordinates of the survey control point must be input to the surveying equipment. In the input work, the work is cumbersome because the operator must input the manual coordinates manually after checking the coordinate values recorded in the cover sheet management book. There was a disadvantage of poor reliability.

In order to solve such problems, a ubiquitous survey environment is being developed, such as a product in which an RFID tag is embedded in the survey control point itself.

RFID (Radio-Frequency IDentification) refers to a technology that recognizes information over a long distance by using radio waves. This requires an RFID tag (hereinafter referred to as a tag) and an RFID reader (reader) (hereinafter referred to as a reader). The tag consists of an antenna and an integrated circuit, which records information in the integrated circuit and sends the information to the reader via the antenna. This information is used to identify the tagged object. In other words, it is similar to a barcode. The difference between RFID and bar code systems is that they use radio waves instead of light. Thus, you can read a tag over a long distance, not just a short distance like a barcode reader, or even receive information through objects in between. RFID can be classified by the power used. RFID, which reads and communicates information on a chip only with the power of a reader, is called passive RFID. Semi-passive RFID is a battery with a built-in tag that uses its power to read chip information and a reader's power to communicate. Finally, active RFID uses the power of tags to both read the information on the chip and communicate that information. RFID is sometimes classified as the frequency of radio waves used for communication instead of power. RFID using low frequency is called Low-Frequency IDentification (LFID), which uses 120-140 kilohertz (khz) of radio waves. High-Frequency IDentification (HFID) uses 13.56 MHz (Mhz), and UHFID (Ultra High-Frequency IDentification), which uses higher frequency, uses radio waves in the 868-956 MHz band.

A survey control point with a built-in RFID tag is a form in which an RFID tag is embedded inside the main body. To install it, the operation of removing a survey point embedded with a new RFID tag and then re-buying a survey control point with a new RFID tag is necessary. do. Therefore, the work is cumbersome, time-consuming and costly, and is a source of unnecessary resource waste. An effective way to create a ubiquitous surveying environment while reusing existing survey control points is being sought.

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide an electronic marker that can create a ubiquitous based surveying environment while using the existing surveying reference point.

Second, another object of the present invention is to provide an electronic marker that can easily check the position of the measurement reference point using the RFID reader.

Third, another object of the present invention is to provide an electronic marker capable of self-development.

Fourth, another object of the present invention is to improve the serial number system by assigning serial numbers reflecting latitude and longitude.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention relates to an electronic indicator which is embedded together in an existing buried surveying reference point and stores measurement information. The disk-shaped body 100 has a disk shape as a whole and a hollow 140 penetrating the upper and lower parts of the center; An RFID tag 200 installed inside the disc-shaped body 100 and storing and storing survey information; An antenna 300 connected to the RFID tag 200 and installed in an annular shape along the inside of the disc-shaped body 100; And a plurality of fixing pins 130 protruding toward the ground from the lower surface of the disc-shaped body 100. The survey information stored in the RFID tag 200 is read by the RFID reader 22. And, it is characterized in that it is installed on the ground so that the existing buried surveying reference point 11 is located in the hollow 140.

Technical effects of the configuration of the present invention are as follows.

First, it is possible to create a ubiquitous survey environment using existing survey control points.

In other words, by installing the RFID tag 200 inside the disk-shaped body 100, the hollow 140 is formed, and the existing buried surveying reference point 11 is located in the hollow 140, the existing buried surveying reference point ( 11) Can be used as it is without removing.

Second, the position of the survey control point can be easily confirmed by using the RFID reader.

In other words, the LED 400 and the beep generator 500 operated by the radio signal transmitted from the RFID reader 22 are provided to easily check the position of the measurement reference point using the naked eye and hearing.

Third, it provides an electronic sign that can develop itself.

In other words, the photovoltaic module 600 and the storage battery 700 are provided so that they can generate their own power and provide semi-permanent use.

Fourth, the serial number system can be improved by assigning serial numbers reflecting latitude and longitude.

In other words, by giving a unique serial number as a sum of latitude and longitude, rather than the conventional simple sequential serial number, it is possible to prevent the occurrence of confusion of the serial number system even in the case of destruction and loss of the survey control point (11), It is also suitable for establishing a national integrated environment.

That is, in the current survey method, the serial number assignment method is composed of two, three, four, ,,, and so on sequentially for each municipality. Duplicates may occur, for example, if the last serial number is 12, the serial number should be 13 if the survey control point is added, but 12 may be assigned if the serial number is not systematically managed. . In addition, each autonomous organization is assigned a serial number sequentially, so the surveying reference point of serial number 3 will exist for each autonomous organization, and there will be more than 250 3 reference points. There is a problem that you can not use the number as it is.

In addition, since the latitude and longitude are stored in the RFID tag 200 itself, the position information can be immediately confirmed using the RFID reader 22 without a separate network communication.

1 is an exploded perspective view of a specific embodiment of the present invention, Figure 2 is a perspective view showing the process and installed state of the existing survey reference point, Figure 3 is a block diagram of the components constituting the present invention.

As shown in FIG. 3, the present invention provides a disc-shaped body 100, an RFID tag 200, an antenna 300, a photovoltaic module 600, a storage battery 700, an LED 400, and a signal sound generator ( 500).

Disc-shaped body 100 is composed of an upper cover 110 and a lower body 120, when the upper cover 110 and the lower body 120 is combined into one, a space is formed inside the RFID tag 200 inside the space ), The antenna 300, the storage battery 700 and the like are built.

Disc-shaped body 100 has a disk shape as a whole and is formed with a hollow 140 penetrating the upper and lower portions of the central portion, when the disc-shaped body 100 is installed on the ground as shown in Figure 2 with a hollow 140 The existing buried survey control point 11 is accommodated in the position.

Therefore, the discoid body 100 surrounding the circumference of the measurement reference point 11 can be installed on the ground while leaving the existing buried measurement reference point 11 intact.

The RFID tag 200 is installed inside the disc-shaped body 100 and survey information is input and stored.

The information stored in this way can be immediately read in the field by the RFID reader 22. Information input to the RFID tag 200 includes latitude, longitude, reference point type, and the like of the measurement reference point 11 as shown in FIG. And serial numbers.

Here, the serial number is not simply a sequential serial number, but a unique value obtained by summing the latitude and longitude values of the corresponding survey control point 11, and thus, in the case of the destruction and loss of the survey control point 11, the serial number system is confused. This does not happen.

Antenna 300 is made of a metal wire such as copper (Cu), is connected to the RFID tag 200 and is installed in an annular shape along the interior of the disc-shaped body (100).

The antenna 300 serves to extend the reading distance (recognition distance) of the RFID reader 22.

The fixing pin 130 protrudes from the lower surface of the disc body 100 (that is, the bottom surface of the lower body 120) toward the ground, and serves to firmly attach the disc body 100 to the ground. do.

On the outer circumferential surface of the fixing pin 130 is further provided with a spiral cut groove 131 helically cut as shown in Figure 1 or 2, the fixing pin 130 is stuck in the ground while the spiral cut groove 131 inside Soil is filled so that the fixing pin 130 in the soft ground can be more firmly attached to the ground.

 The LED 400 is provided on the surface of the upper cover 110 so that the position of the disc-shaped body 100 can be easily visually identified by repeatedly turning on and off according to a radio signal transmitted from the RFID reader 22.

The radio signal transmitted from the RFID reader 22 may be a radio wave transmitted by the RFID reader 22 to read information stored in the RFID tag 200, or a radio wave separately for remotely controlling the operation of the LED 400. In addition, a circuit for controlling the operation of the LED 400 by receiving such a radio signal should be provided in the LED (400).

The period or time of blinking is not particularly limited and various pattern combinations are possible.

The signal generating unit 500 may be provided on the surface of the upper cover 110 or may be provided inside the disc-shaped body 100. The signal-generating unit 500 may generate a pre-stored signal sound according to a radio signal transmitted from the RFID reader 22 to form a disc body. The location of the 100 can be easily identified using hearing.

The radio signal transmitted from the RFID reader 22 may be a radio wave transmitted by the RFID reader 22 to read information stored in the RFID tag 200, or a radio wave separately for remotely controlling the operation of the LED 400. In addition, a circuit for controlling the operation of the beep generator 500 by receiving such a radio signal should be provided in the beep generator 500.

The specific content of the signal tone is not particularly limited and may provide prerecorded voice information.

When the solar power module 600 is further provided on the surface of the upper cover 110, power generation may be performed using solar light in general.

In addition, the disc body 100 may be further provided with a storage battery 700 for storing the power produced by the photovoltaic module 600.

As such, the power stored in the battery 700 is supplied as the power necessary for the operation of the RFID tag 200, the LED 400, and the signal generator 500.

Therefore, the RFID tag 200, the LED 400 and the beep generator 500 can be operated semi-permanently even without replacing the power supply or the battery from the outside.

In particular, semi-passive RFID can be implemented by supplying power to the RFID tag 200. Here, semi-passive RFID is supplied with power to the RFID tag 200 to provide information. The power is used for reading, and the power of the RFID reader 22 is used for communication.

As such, when power is supplied to the RFID tag 200, the reading distance may be doubled compared to the passive type.

As described above, the technical spirit of the present invention has been described with reference to specific embodiments of the present invention, but the protection scope of the present invention is not necessarily limited to these embodiments, and various designs may be made without changing the technical spirit of the present invention. Changes, additions or deletions of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

1 is an exploded perspective view of a specific embodiment of the present invention.

Figure 2 is a perspective view showing the process and the installed state of the existing survey reference point.

3 is a block diagram of the components constituting the present invention.

4 is an example of survey information stored in an RFID tag.

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

100: disc body

110: upper cover

120: lower body

130: fixing pin 131: spiral cut groove

140: Hollow

200: RFID Tag

300: antenna

400: LED

500: beep generator

600: solar power module

700: storage battery

11: Survey Control Point

22: RFID Reader

Claims (6)

The present invention relates to an electronic marker that stores survey information and is embedded at an existing embedded survey control point. A disk-shaped body 100 having a disk shape as a whole and having a hollow 140 penetrating the upper and lower parts of the central part; An RFID tag 200 installed inside the disc-shaped body 100 and storing and storing survey information; An antenna 300 connected to the RFID tag 200 and installed in an annular shape along the inside of the disc-shaped body 100; And, A plurality of fixing pins 130 protruding toward the ground from the lower surface of the disc-shaped body 100; It is configured to include, Surveying information stored in the RFID tag 200 is read by the RFID reader 22, Surveying reference point electronic marker, characterized in that installed on the ground so that the existing buried surveying reference point 11 is located in the hollow 140. In claim 1, wherein the disc body 100, Upper cover 110; And, A lower body 120 positioned on a lower surface of the upper cover 110 and having a shape corresponding to that of the upper cover 110; Consists of the reference cover electronic marker, characterized in that the upper cover 110 and the lower body 120 is coupled to form the disc-shaped body (100). In claim 2, An LED 400 installed on a surface of the upper cover 110 and repeating lighting and turning off according to a radio signal transmitted from the RFID reader 22; And, A signal sound generating unit 500 installed on one surface of the upper cover 110 or the inner side of the disc-shaped body 100 and generating a pre-stored signal sound according to a radio signal transmitted from the RFID reader 22; Surveying reference point electronic marker, characterized in that is further provided. In the information input to the RFID tag 200, A survey reference point electronic marker, characterized in that the latitude, longitude, reference point type, and serial number of the existing buried survey reference point (11) is included. In claim 4, The surface of the upper cover 110, the photovoltaic module 600; Is further provided, A storage battery 700 storing the power produced by the photovoltaic module 600 in the disc-shaped body 100; Is equipped with more The storage battery 700 is a survey reference point electronic marker, characterized in that for supplying the power required for the operation of the RFID tag 200, the LED 400 and the beep generator 500. In claim 5, the fixing pin 130, A spiral cut groove 131 spirally cut along the outer circumferential surface; Surveying reference point electronic marker, characterized in that is further provided.

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