KR200375700Y1 - High precise dgps system device providing error correction information and geographical information using internet - Google Patents

Abstract

The digital PS system of the present invention includes a plurality of reference station information receivers to receive error correction information transmitted as a medium frequency signal from a plurality of reference stations. The reference station information receiver provides error correction information to the main server via the Internet. The main server collects error correction information provided from a plurality of reference station information receivers and provides corresponding error correction information to a user terminal connected through a wired or wireless Internet. The user terminal corrects the coordinate information received from the satellite by using the error correction information to obtain high precision coordinate information. BEACON receiver for receiving the error correction information is configured in the reference station information receiver to make the user terminal lighter and easier to install and use.

Description

HIGH PRECISE DGPS SYSTEM DEVICE PROVIDING ERROR CORRECTION INFORMATION AND GEOGRAPHICAL INFORMATION USING INTERNET} Using the Internet to Provide Error Correction Information and Geographic Information

The present invention relates to a differential GPS (DGPS) system device, specifically, by collecting error correction information provided from a plurality of reference stations through the Internet to provide a stable position correction service to users connected to the Internet The present invention relates to a high-precision digital PS system device that provides error correction information and geographic information using the Internet.

The GPS (Global Positioning System) system is a satellite positioning system that can determine the current position or time using satellites. The GPS system obtains the position of the viewpoint by receiving the radio wave emitted from the satellite that knows the exact position and measuring the time required to the viewpoint. Recently, with the rapid development of the information and communication field, the application fields and application technologies of the GPS system are rapidly developing and diversifying. In GPS systems, the measured values include errors due to satellite clocks, satellite orbits, ionospheric propagation delays, and efforts to minimize such error factors continue. The most widely used method is the differential GPS (DGPS) system.

1 is a view showing the structure of a general DGPS system. Referring to the drawings, the DGPS system requires two GPS receivers, one of which is provided in a fixed reference station 20 and the other of which is provided in a mobile DGPS receiver 30.

The DGPS receiver 30 has a GPS receiver 32 and a BEACON receiver 34, where the GPS receiver 32 receives the coordinate information provided from the satellite 10, and the BEACON receiver 34 receives the reference station 20. Receive error correction information according to the RTCM (Radio Technical Commission for Maritime) protocol provided through the medium-wave signal. The DGPS receiver 30 corrects the received coordinate information using the error correction information to calculate a more accurate coordinate value and provides the user terminal 40 to the user terminal 40 according to the National Marine Electronics Association (NMEA) protocol. The DGPS receiver 30 and the user terminal 40 may be connected by RS232C serial communication. The user terminal 40, which has received the coordinate value with the error correction, displays the latitude and longitude coordinates based on the WGS84 coordinate system.

However, since the DGPS system is composed of expensive equipment, it is difficult to generalize the system, and the installation process of the DGPS receiver is complicated, and a professional manpower having professional installation and operation skills is required. In addition, the BEACON receiver mounted on the DGPS receiver uses a medium frequency signal, which causes a problem in that a smooth communication cannot be performed in the case of a considerable distance from a reference station or in an urban area with a lot of radio obstacles. In particular, in the case of us, the reference stations are composed of coastal centers, so this problem can be more likely to occur inland.

Accordingly, an object of the present invention is to solve the above-mentioned problems, and collects error correction information through a reference station information receiver capable of stably receiving a medium frequency signal generated from a plurality of reference stations. By providing the error correction information to the user terminal through to provide a digital PS system device capable of high-precision stable position tracking.

Another object of the present invention is to configure the BEACON receiver for receiving the error correction information provided from the reference station to the reference station information receiver to reduce the weight of the user terminal and to provide an easy to install and use the digital PS system device have.

Another object of the present invention is to provide a digital PS system device capable of high-precision position tracking by providing error correction information to a user terminal based on the Internet, and providing topographic maps and cadastral map information.

According to a feature of the present invention for achieving the object of the present invention as described above, the high-precision digital PS system device for providing error correction information and geographic information using the Internet stably receives the medium wave signals generated from a plurality of reference stations A plurality of reference station information receivers disposed close to the plurality of reference stations for receiving and receiving error correction information from the plurality of reference stations via medium frequency signals; It is connected to a number of reference station information receivers through the Internet, collects error correction information, performs primary error correction, and responds to requests from user terminals connected to the Internet. A main server providing a user terminal; It includes a user terminal that receives the error correction information and geographic information corresponding to its location to the main server, receives coordinate information from the satellite, and performs error correction based on the error correction information to track and display the current location. do.

In a preferred embodiment of the present invention, the plurality of base station information receivers, the main server, the main server and the user terminal are each connected to the wireless Internet or wired Internet.

In a preferred embodiment of the present invention, the main server includes: an RTCM management unit for managing error correction information; A user manager for managing user information of the user terminal; A communication manager providing error correction information and map information corresponding to the user terminal to the user terminal in response to the error correction information request and the geographic information request of the user terminal; A digital map manager 74 for managing digital map information; And a main server database including an RTCM database for storing error correction information, a connection management database for storing connection information of a user terminal, a topographical database for storing topographical information, and an cadastral database for storing cadastral information.

In a preferred embodiment of the present invention, the user terminal includes a user terminal function block, a GPS receiver for receiving coordinate information by satellite, and a communication interface connected between the user terminal function block and the GPS receiver.

In a preferred embodiment of the present invention, the communication interface is a first transceiver to be connected to the GPS receiver, a second transceiver to be connected to the user terminal function block, and the voltage level between the first transceiver and the second transceiver. It includes a communication conversion module for converting each other.

In a preferred embodiment of the present invention, the user terminal functional block includes: a first transceiver for connecting to a main server; A second transceiver unit connected to the communication interface; A display for displaying geographic information; A memory for storing error correction information, coordinate information, and topographic maps and map information; And a processor configured to correct an error of the coordinate information based on the error correction information, and a process of displaying the map degree / indicator information according to the corrected coordinate information.

The digital PS system of the present invention reliably collects the error correction information through the reference station information receiver arranged to stably receive medium frequency signals generated from a plurality of reference stations, and the user through the wired / wireless Internet. By providing the terminal, the user terminal can be stably tracked with high precision.

Embodiment of the present invention may be modified in various forms, the scope of the present invention should not be construed as being limited by the embodiments described below. This embodiment is provided to more clearly explain the present invention to those skilled in the art.

(Example)

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

2 is a block diagram of a high-precision DGPS system according to a preferred embodiment of the present invention. Referring to the drawings, the digital PS system of the present invention collects error correction information based on the Internet 60 and provides it to the user terminal 90. The system includes a plurality of reference station information receivers 50 for receiving error correction information from a plurality of reference stations 20.

The reference station information receiving unit 50 is preferably located close to the reference station 20 so as to stably receive the medium wave signal generated from the reference station 20. In particular, in the case of our country, since the reference station 20 is disposed around the coast, a plurality of reference station information receivers 50 are appropriately distributed in each region. A plurality of reference station information receivers 50 are connected to the main server 70 via the Internet 60, which can be either wireless or wired Internet. The reference station information receiving unit 50 receives the error correction information from the plurality of reference stations 20 through the medium wave signal and provides it to the main server 70.

The main server 70 responds to the request for error correction information from the RTCM manager 71 for managing error correction information, the user manager 72 for managing user information of the user terminal 90, and the user terminal 90. Communication management unit 73 for providing the error correction information to the user terminal 90, the digital map management unit 74 for managing the digital map information. And an RTCM database 76 storing error correction information in the main server database 75, a connection management database 77 storing connection information of the user terminal, a topographic map database storing topographic map information, and an cadastral map storing cadastral information. A database 79 is included and configured.

The main server 70 receives and receives error correction information from a plurality of reference station information receivers 50 and performs primary error correction. According to the request of the user terminal 90, the first error correction information corresponding thereto is provided to the user terminal 90 through wired or wireless Internet. For example, as shown in FIG. 2, in the case of the user terminal 90 connected to the wireless Internet through the mobile communication network base station 80, error correction information is provided to the wireless Internet through the mobile communication network base station 80. However, even in the case of a user terminal connected to a wired Internet, it is possible to provide error correction information in the same manner.

The user terminal 90 is largely connected to the user terminal function block 92 and the GPS receiver 110 for receiving coordinate information via satellite, and the communication interface 100 connected between the user terminal function block 92 and the GPS receiver 110. It includes. In this embodiment, the user terminal 90 is a PDA, but various communication devices or personal computers capable of accessing the Internet can be used as user terminals.

The communication interface 100 includes a first transceiver 101 and 102 connected to the GPS receiver 110, a second transceiver 104 connected to a user terminal function block 92, and a first transceiver 101. And a communication conversion module 103 for mutually converting a voltage level between the second transmission unit 104 and the second transmission / reception unit 104. The communication conversion module 103 performs the mutual conversion between the communication voltage level of the GPS receiver 110 + 3V ~ -3V and the communication voltage level of + 12V ~ -12V of the PDA block 92. The second transceiver 104 supports RS232C serial communication.

The user terminal function block 92 may include a first transceiver 93 (for example, a CDMA module) for connecting to the main server 70 and a second transceiver 94 (RS232C) for connecting to the communication interface 100. Serial communication), a display 96 for displaying geographic information, a processor 95, and a memory 97. The memory 97 stores error correction information 97a, coordinate information 97b, and topographic map / indicator information 97c. The processor 95 uses a process AP1 for correcting the error of the coordinate information 97b based on the error correction information 97a and the geospatial / indicator information 97 according to the corrected coordinate information. A process AP2 of displaying geography on the display 96 is performed.

In order to use the Digi-PS system, the user terminal 90 only needs to have a GPS receiver, so that the installation or use of equipment is very simple. In addition, unlike the prior art because it is not equipped with a BEACON receiver is very light weight and convenient to carry, it is possible to configure the user terminal at a low cost. This makes the Digi-PS system more versatile.

As described above, the configuration and operation of the high-precision digital PS system using the Internet according to a preferred embodiment of the present invention is shown in accordance with the above description and drawings, but this is merely described as an example and does not depart from the spirit of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the scope of the present invention.

According to the present invention as described above, by collecting the error correction information through the reference station information receiving unit that can stably receive the medium frequency signals generated from a plurality of reference stations by providing the error correction information to the user terminal through the wired and wireless Internet It can provide a stable digital PS system. In addition, by configuring a BEACON receiver for receiving error correction information in the reference station information receiver, the user terminal can be made lighter in weight, and its installation and use are easy.

1 shows the structure of a typical DigiPS system;

2 is a block diagram of a high-precision digital PS system apparatus according to an embodiment of the present invention;

3 is a detailed configuration diagram of the main server of FIG. 2;

4 is a schematic structural diagram of a user terminal; And

5 is a detailed block diagram of the communication interface and the PDA functional block of FIG.

* Description of the symbols for the main parts of the drawings *

10: satellite 20: reference station

30: DGPS receiver 32, 110: GPS receiver

34: BEACON receiver 50: reference station information receiver

60: Internet 70: main server

80: mobile communication network base station 90: user terminal

92: PDA block 100: communication interface

Claims (6)

In a digital PS system that tracks a current position by correcting an error of location information based on location information provided from a plurality of satellites and error correction information provided from a plurality of reference stations: A plurality of reference station information receivers disposed close to the plurality of reference stations to stably receive the medium frequency signals generated from the plurality of reference stations, and receiving error correction information through the medium frequency signals from the plurality of reference stations; It is connected to a number of reference station information receivers through the Internet, collects error correction information, and performs primary error correction.In response to the request of a user terminal connected to the Internet, the primary error correction information and geographic information A main server provided to a user terminal; It includes a user terminal that receives the error correction information and geographic information corresponding to its location to the main server, receives coordinate information from the satellite, and performs error correction based on the error correction information to track and display the current location. High-precision digital PS system apparatus for providing error correction information and geographic information using the Internet, characterized in that. According to claim 1, wherein the plurality of base station information receiver, the main server, the main server and the user terminal is a high-precision digital providing error correction information and geographic information using the Internet, characterized in that each connected via a wireless Internet or a wired Internet PS system device. The apparatus of claim 1, wherein the main server comprises: an RTCM manager for managing error correction information; A user manager for managing user information of the user terminal; A communication manager providing error correction information and map information corresponding to the user terminal to the user terminal in response to the error correction information request and the geographic information request of the user terminal; A digital map manager 74 for managing digital map information; And And a main server database including an RTCM database for storing error correction information, a connection management database for storing connection information of a user terminal, a topographic database for storing topographical information, and an cadastral database for storing cadastral information. High-precision digital PS system device that provides error correction and geographic information using the Internet. 2. The user terminal of claim 1, wherein the user terminal comprises a user terminal function block, a GPS receiver for receiving coordinate information via satellite, and a communication interface connected between the user terminal function block and the GPS receiver. High precision digital PS system device that provides error correction information and geographic information. The communication interface of claim 4, wherein the communication interface converts a voltage level between the first transceiver unit connected to the GPS receiver, the second transceiver unit connected to the user terminal function block, and the first transceiver unit and the second transceiver unit. High precision digital system system providing error correction information and geographic information using the Internet characterized in that it comprises a communication conversion module. The apparatus of claim 4, wherein the user terminal function block comprises: a first transceiver for connecting to a main server; A second transceiver unit connected to the communication interface; A display for displaying geographic information; A memory for storing error correction information, coordinate information, and topographic maps and map information; And a processor that performs a process of correcting an error of coordinate information based on the error correction information, and a process of displaying a geography of a current location by using the map degree / indicator information according to the corrected coordinate information. High-precision digital PS system device that provides error correction information and geographic information.