KR20180032300A - Apparatus and method for generating differential global navigation satellite system pseudo range correction information - Google Patents

Abstract

The present invention relates to a DGNSS pseudo range correction information generating device and a method thereof. The device receives observation precise coordinates of a reference station and observation data with respect to GNSS satellites from the reference station which observes the same GNSS satellites as GNSS satellites observed in a user terminal. The device allows the user terminal to generate pseudo range correction information per a GNSS satellite based on the precise coordinates and the observation data, thereby providing improved location information to a user.

Description

TECHNICAL FIELD [0001] The present invention relates to a DGNSS pseudo range correction information generating apparatus and a DGNSS pseudo distance correction information generating apparatus,

The present invention relates to an apparatus and method for generating DGNSS pseudorange correction information, and more particularly to an apparatus and method for generating DGNSS pseudorange correction information by receiving precise coordinates of a reference station and observation data for GNSS satellites from a reference station, The present invention relates to an apparatus and a method for providing location information more improved to a user.

With the development of industrial technology and the rapid development of communication technology, modern society has emphasized mobility, and the demand for positioning technology or positioning system for calculating user location information is rapidly increasing. The location - based industry using such location information is emerging as a new major industrial field.

A typical positioning system for calculating user's location information is GNSS (Global Navigation Satellite System) using navigation satellite.

In general, GNSS is a satellite navigation system that computes the position, altitude, and speed of an object moving or stationary throughout the earth using signals from a navigation satellite orbiting the orbit, It is used in various fields such as surveying, traffic, aviation, space field, facility management, cemetery management as well as application.

However, the navigation satellite signal used when calculating the user's location information using the GNSS is distorted while passing through the earth's atmosphere, the navigation satellite includes an error in estimation of the position and time, A positional error of usually several tens of meters may occur due to multi-path error and noise at the point. As a result, the position information calculated by the GNSS receiver necessarily deviates from the actual information.

This difference is particularly important for special areas where a high level of location accuracy is required, such as location-based service (LBS), aircraft, ship or car service, precision surveying, emergency rescue, The same problem can be caused.

In order to maintain a high level of position accuracy using GNSS, it is very important to remove the errors contained in the satellite navigation signal before determining the position of the GNSS receiver that receives the navigation signal from the navigation satellite.

In order to solve such a problem, recently, DGNSS (Differential GNSS, DGNSS) has been developed and applied to GNSS.

The DGNSS is a system that grasps the user's position (precisely, the position of the user's terminal) and provides precise time information to the user. The DGNSS uses the pseudo range correction (PRC) It has the advantage of being able to improve quickly and accurately.

The DGNSS generates pseudo distance correction information by calculating a positioning error in a reference point that knows the precise position in advance (that is, position information of a previously measured reference station), and transmits the pseudo range correction information to the terminal of the user observing the same satellite as the reference point The generated pseudo distance correction information is provided in real time so that the positioning result calculated by the terminal of the user can be corrected so that the user can be provided with the improved position information.

Further, the GNSS generates pseudo distance correction information by assuming that the error factors are the same within a range of a distance between a reference point that is the position information of the reference station and a user within a range of several tens km, and transmits the generated pseudorange correction information to the Networked Transport of the user's terminal through a communication service such as RTCM via Internet Protocol (NTRIP), Digital Multimedia Broadcasting (DMB), and beacon, thereby maintaining the positional accuracy of the user.

However, in the conventional GNSS, since the pseudo range correction information is generated only in the reference station and provided to the terminal provided by the user, if the communication is not performed well, or communication interruption or signal interference phenomenon occurs temporarily The pseudo distance correction information can not be received in real time, so that the accurate position of the user can not be calculated and the position accuracy of the user is greatly reduced.

In addition, since the conventional GNSS generates and provides the pseudorange correction information for all users, the processing load is concentrated on the base station and the pseudo distance correction information can not be generated due to a defect in the reference station Can occur.

Therefore, in the present invention, the reference station data including the precise coordinates of the reference station and the satellite observation data are received in real time from the reference station observing the same satellite as the user terminal, and based on the reference station data, And applying the generated pseudo range correction information to the GNSS satellite observation data received through the GNSS receiver provided in the user terminal, thereby obtaining a more accurate user location information and a method thereof I want to.

The present invention also provides an apparatus and method for distributing a load concentrated on a reference station by allowing pseudo distance correction information generated and provided only in a reference station to be generated in each user's terminal.

Next, a brief description will be given of the prior arts that exist in the technical field of the present invention, and technical matters which the present invention intends to differentiate from the prior arts will be described.

Korean Patent No. 1152399 (Jun. 25, 2012) relates to a method of calculating a distance error estimation value for a reference station apparatus and a pseudo distance correction information applied thereto of a satellite radio navigation system, Distance information including signal delay information by the ionosphere and the troposphere, generates a distance error estimate for the pseudorange correction information based on the generated pseudorange error information, To a terminal, and to perform positioning of the user terminal.

Although the prior art is similar to the present invention in that location information of a user is calculated on the basis of pseudo range correction information, since the pseudo distance correction information for all users is generated and provided in the reference station, The processing performance is reduced, or a defect is generated in the reference station, so that accurate pseudorange correction information can not be generated in real time.

Also, in the prior art, when the communication is not performed well or the communication interruption or signal interference phenomenon occurs according to the surrounding environment in which the user is located, the pseudo range correction information generated by the reference station can not be received in real time from the user terminal There is a problem that the accurate position of the user can not be calculated.

However, according to the present invention, the precise coordinates of the reference station measured in advance from the reference station and the observation data of the GNSS satellite observed at the reference station are received, and pseudorange correction information is transmitted from the user terminal It is possible to distribute the load of the reference station and to maintain a high level of position accuracy.

The present invention also provides a method of controlling a pseudo range of a base station by using pseudo distance correction information generated in the past even if the communication with the reference station is not performed well or the reference station data is not received from the reference station due to a temporary communication interruption or signal interference phenomenon. The location information of the user can be calculated so that the position accuracy of the user can be continuously maintained.

Korean Patent Registration No. 1391916 (Apr. 25, 2014) discloses a GPS positioning system using ultra-fast track power and a GPS positioning method thereof. The GPS positioning system receives GPS satellite information from GPS satellites and receives GPS satellite information from IGS (International GPS Service) The pseudo range correction information is generated based on the received GPS satellite information and the super quick ephemeris to provide the pseudo distance correction information to the user so that positioning can be performed on the user based on the pseudo distance correction information System and a method thereof.

Although the prior art is similar to the present invention in that pseudorange correction information is generated to perform positioning with respect to the user, the present invention is not limited to generating the pseudorange correction information at the reference station, Y coordinates of the reference station and the satellite observation data of the reference station in real time and generates pseudorange correction information by itself in the receiving user terminal, The positional accuracy of the user is improved by applying the generated pseudorange correction information to the observation data, and the prior art does not describe or suggest the technical features of the present invention.

An embodiment of the present invention is created to solve such a problem as described above. The present invention receives reference station data including reference station precise coordinates and reference station GNSS satellite observation data from a reference station, So as to provide improved positional accuracy to the user by applying the generated pseudorange correction information when generating the pseudo distance correction information and calculating the user's location information using the GNSS satellite observation data received at the user terminal And an object thereof is to provide an apparatus and a method thereof.

Also, in an embodiment of the present invention, even when communication between the reference station and the user terminal is difficult according to the surrounding environment in which the user is located, the position information of the user can be calculated using the pseudo range correction information generated and stored in the past And an apparatus and method for continuously maintaining the accuracy of false positives with respect to a user.

In addition, an embodiment of the present invention is an apparatus and method for distributing a load concentrated on a reference station by allowing a user terminal to generate pseudo distance correction information on its own based on reference station data received from a reference station And to provide the above objects.

In addition, an embodiment of the present invention can distribute the load concentrated on the reference station through the GNSS pseudorange correction information generator, and can minimize the cost of installation of the reference station, So that the distance between the reference station and the user can be minimized, thereby providing more accurate position information to the user.

An apparatus for generating DGNSS pseudorange correction information in a user terminal according to an exemplary embodiment of the present invention includes a pseudorange correction information generator for generating pseudorange correction information based on reference station data received from a reference station in a user terminal, A user GNSS observation data receiving unit for receiving user GNSS observation data from the user terminal, and a user location information calculating unit for calculating user location information from the pseudo range correction information and the received user GNSS observation data.

In addition, the reference station data may include the GNSS topographic observation data including the reception time at which the satellite navigation signal transmitted from the plurality of GNSS satellites is received at the reference station, and the precise coordinates of the reference station.

A reference station data receiving unit for receiving reference station data for a plurality of satellites from a reference station and a reference station position information calculating unit for calculating position information of the reference station using the received observation data for each GNSS level, The pseudo range correction information generator compares the calculated position information with the precise coordinates of the received reference station and calculates an error with respect to the calculated position information to thereby generate the pseudo range correction information.

Also, the user location information calculation unit may calculate pseudoranges for each GNSS based on observation data for a plurality of GNSS satellites received through a GNSS receiver installed in the user terminal or outside the user terminal, And calculates the position information for the user by reflecting the generated pseudo distance correction information to the distance.

A method of generating DGNSS pseudorange correction information in a user terminal according to an embodiment of the present invention includes generating pseudorange correction information based on reference station data received from a reference station in a user terminal A user GNSS observation data reception step of receiving the user GNSS observation data from the user terminal, and a user location information calculation step of calculating user location information from the pseudo range correction information and the received user GNSS observation data. do.

In addition, the reference station data may include the GNSS topographic observation data including the reception time at which the satellite navigation signal transmitted from the plurality of GNSS satellites is received at the reference station, and the precise coordinates of the reference station.

The method also includes a reference station data reception step of receiving reference station data for a plurality of satellites from the reference station, and a reference station position information calculation step of calculating position information of the reference station using the received observation data of the GNSS position Wherein the step of generating the pseudo range correction information compares the calculated position information with the precise coordinates of the received reference station and calculates an error with respect to the calculated position information, .

The user location information calculation step calculates the pseudoranges for each GNSS based on the observation data of the plurality of GNSS satellites received through the GNSS receiver provided in the user terminal or outside the user terminal, And the position information for the user is calculated by reflecting the generated pseudo distance correction information to the pseudo distance.

1 is a conceptual diagram for schematically explaining an apparatus and method for generating DGNSS pseudorange correction information according to an embodiment of the present invention.
2 is a block diagram illustrating a configuration of a GNSSS pseudorange correction information generating apparatus according to an embodiment of the present invention.
3 is a flowchart illustrating a procedure for generating pseudo range correction information through a DGNSS pseudorange correction information generator according to an exemplary embodiment of the present invention to calculate position information of a user.
FIG. 4 is a block diagram showing a configuration of a DGNSS pseudorange correction information generating apparatus according to an embodiment of the present invention. Referring to FIG. 4, when the communication between the reference station and the DGNSS pseudorange correction information generating apparatus is poor or temporary communication is lost, FIG. 7 is a flowchart illustrating a procedure for calculating location information. FIG.

Hereinafter, an apparatus and method for generating DGNSS pseudorange correction information according to the present invention will be described in detail with reference to the accompanying drawings. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. Like parts are designated with like reference numerals throughout the specification.

1 is a conceptual diagram for schematically explaining an apparatus and method for generating DGNSS pseudorange correction information according to an embodiment of the present invention.

As shown in FIG. 1, the DGNSS pseudo distance correction information generating apparatus 100 provided in the user terminal 300 receives reference station data in real time from the reference station 200 through a communication network.

The reference station data also includes the GNSS satellite observation data and precise coordinates which are positional information of the reference station 200 previously measured.

Meanwhile, the communication network includes a mobile communication network including WAVE (Wireless Access in Vehicular Environments), LTE and 3G, a Networked Transport of RTCM via Internet Protocol (NTRIP), Digital Multimedia Broadcasting (DMB) Beacon, and the like.

The reference station 200 may also include a GNSS receiver 210 for receiving satellite navigation signals from a plurality of GNSS satellites and a communication unit 220 for communicating with the DGNSS pseudorange correction information generator 100 have.

The GNSS receiver 210 receives satellite navigation signals from a plurality of GNSS satellites and generates observation data for the received satellite navigation signals to generate DGNSS pseudorange correction information generator 100).

On the other hand, the satellite navigation signal includes the time of the clock mounted on each satellite, identification information of the satellite, state information of the satellite, orbit information (current position of the satellite), and ionospheric delay compensation coefficient. Each of the information contained in the satellite navigation signal is information that is generally used for positioning in the GNSS, so a detailed description thereof will be omitted.

The observation data generated by the reference station 200 is configured to include the respective information included in the satellite navigation signal at the time when the satellite navigation signal was received from each GNSS satellite.

Also, the reference station communication unit 220 transmits the 3D precise coordinates (x, y, z), which is the position information of the reference station previously stored and stored, and the generated observation data to the DGNSS pseudorange correction information generating apparatus 100 .

The observation data transmitted at this time is composed of four or more, and each of the observation data is generated based on a satellite navigation signal received from each of at least four or more GNSS satellites.

The reason why at least four observational data are required is to synchronize (i.e., synchronize in time) the GNSS with the reference station and calculate three-dimensional position information (latitude, longitude, and altitude) of the reference station.

Also, the DGNSS pseudorange correction information generator 100 calculates a pseudo-range for each statue based on the received observation data.

The pseudo range refers to the approximate distance between the GNSS satellite and the reference station 200. The pseudorange is a distance from the GNSS satellite to the GNSS receiver 210 of the reference station 200, .

This pseudorange may include a distance error due to a time delay caused by the ionosphere or the convection layer.

Further, the DGNSS pseudo range correction information generator 100 calculates three-dimensional coordinates of the reference station 200 based on the generated pseudoranges.

That is, the DGNSS pseudorange correction information generator 100 measures the propagation time of the satellite navigation signals of the respective GNSS satellites based on the received observation data for each GNSS satellite, Calculates the distance, that is, the pseudo distance, and calculates the position information of the reference station 200 using the calculated pseudo distance.

The DGNSS pseudo distance correction information generating apparatus 100 also calculates the position information of the reference station 200 and the precise coordinates of the reference station 200 received from the reference station 200, And compares the calculated positional information with the positional information of the reference station to generate GNSS pseudorange correction information.

Also, the DGNSS pseudo distance correction information generating apparatus 100 generates a pseudorange distance correction information for each GNSS satellite calculated based on user GNSS observation data for a plurality of GNSS satellites observed and received from a GNSS receiver (not shown) And correct position information of the user is calculated by reflecting the generated pseudo distance correction information to the pseudo distance.

And outputs the calculated position information to an output device such as a display (not shown) included in the user terminal 300, thereby providing the output information to the user.

Further, the DGNSS pseudo range correction information generating apparatus 100 may be configured to generate the pseudo distance correction information based on the calculated position information of the user, the pseudo range correction information reflected in the calculated position information of the user and the GNSS satellite observed when calculating the position information of the user And maps and stores the identification information.

Also, the DGNSS pseudo range correction information generating apparatus 100 may not communicate with the reference station 200 according to the surrounding location where the user is located, or may transmit the reference station data from the reference station 200 in real time In the case where the pseudo distance correction information can not be received, the location information of the user can be calculated using the past pseudo distance correction information stored.

That is, when the reference station data can not be received from the reference station in real time, the DGNSS pseudorange correction information generating apparatus 100 generates the user GNSS observation data received from the GNSS receiver provided in the user terminal 300, , Calculates the pseudo distance for each GNSS and calculates the location information of the corresponding user. Also, the past user position information of the past is retrieved and pseudo distance correction information reflected in the past position information of the user who is near to the current position information of the user is extracted. The extracted pseudo range correction information is then reflected in the calculated pseudo range of the GNSS, so that accurate position information of the user is calculated and the improved position accuracy can be maintained.

On the other hand, the DGNSS pseudorange correction information generator 100 searches at least one past location information of the nearest user, extracts the pseudo distance correction information reflected in the past location information of the user, The new pseudo range correction information can be generated by averaging or calculating the median value for the correction information and the new pseudorange correction information is reflected in the pseudo range for each GNSS in order to calculate the accurate position information of the user It is possible.

Meanwhile, the past user location information searched by the DGNSS pseudo distance correction information generation apparatus 100 includes user location information generated by observing the same GNSS satellite as the observed GNSS satellite to calculate the current location information of the user it means.

As described above, the DGNSS pseudorange correction information generation apparatus 100 of the present invention is provided in the user terminal 300, so that the pseudo range correction information can be generated in the user terminal 300 itself , It is possible to generate the pseudorange correction information generated only by the existing reference station at the user terminal so that the load concentrated on the reference station is distributed to each user terminal and at the same time, So that the positional accuracy of the user can be maintained even in the case of a failure or communication disconnection.

2 is a block diagram illustrating a configuration of a GNSSS pseudorange correction information generating apparatus according to an embodiment of the present invention.

2, the GNSS pseudo distance correction information generating apparatus 100 includes a reference station data receiving unit 110 for receiving and collecting reference station data from a reference station, A pseudo range correction information generator 130 for generating pseudo range correction information that is pseudo range correction information using the calculated reference station position information, A user GNSS observation data receiving unit 140 that receives observation data of the GNSS satellite from the GNSS receiver, a user location information calculation unit 150 that calculates location information of the user, and a memory 160.

The reference station data receiving unit 110 also receives reference station data in real time from a specific reference station 200 that is included in the user terminal 300 itself or observes the same GNSS satellite as the external GNSS receiver.

The reference station data includes precise coordinates of the reference station 200 and respective observation data for a plurality of GNSS satellites observed from the reference station 200.

Also, the precise coordinates of the reference station 200 means position information of the reference station 200 precisely measured in advance, and the observation data is composed of observation data for at least four or more GNSS satellites.

The reference station position information calculation unit 120 also calculates position information (three-dimensional coordinates) of the reference station based on the received observation data.

In order to calculate the position information of the reference station 200, the reference station position information calculation unit 120 calculates the position information of the reference station 200 based on the transmission time of the satellite navigation signal for each GNSS position included in the observation data, And extracts the reception time of the GNSS satellite-based navigation signal.

The reference station position information calculation unit 120 calculates the difference between the transmission time and the reception time of the satellite navigation signal for each GNSS by using the transmission time and reception time of the extracted satellite navigation signal for each GNSS , And calculates the pseudoranges for each of the above GNSSs by converting them into distances.

Also, the reference station position information calculation unit 120 calculates the position information, which is the three-dimensional coordinates of the corresponding reference station, using the calculated pseudo range for each GNSS position by using the trilateration principle.

Meanwhile, the calculation of the location information using the trilateration principle is generally applied to the existing DGNSS, so a detailed explanation will be omitted.

That is, the location information of the reference station is roughly calculated based on the satellite navigation signals received from four or more GNSS satellites, and may include various errors such as ionospheric delay error, tropospheric delay error, and the like.

Accordingly, the pseudo distance correction information generating unit 130 generates pseudo distance correction information capable of removing the error.

The pseudo distance correction information generation unit 130 compares the position information of the reference station 200 calculated through the reference station position information calculation unit 120 with the precise coordinates of the received reference station 200 , And generates pseudo distance correction information so that the error value can be corrected.

Also, the user GNSS observation data receiving unit 140 receives the user GNSS observation data from the GNSS receiver provided in the user terminal 300 itself or the outside.

Also, the user location information calculation unit 150 calculates pseudoranges for each GNSS using the GNSS observation data received through the user GNSS observation data receiving unit 140.

The calculated pseudoranges for each GNSS may include various errors such as ionospheric delay error, tropospheric delay error, and the like.

Further, the user location information calculation unit 150 calculates the precise location information of the user by applying the pseudo distance correction information generated by the pseudo distance correction information generation unit 130 to the calculated pseudo distance according to the GNSS gender, And outputs it to be provided to the user.

Meanwhile, a series of processes of calculating and outputting the precise position information of the user is performed in real time, and thus the position accuracy of the user can be continuously maintained.

In addition, since it is assumed that the error factors are the same within a range in which the baseline distance between the reference station 200 and the user is within a range of several tens km, the elimination effect of the error factors by the generated pseudo- Satellite orbit error, ionospheric delay error, and tropospheric delay error.

Also, the DGNSS pseudorange correction information generating apparatus 100 may generate the pseudo distance correction information reflecting the final position information of the user, the pseudo distance correction information reflected to calculate the position information of the user, And maps and stores the identification information on the GNSS satellite.

In addition, when the communication with the reference station 200 is defective or is disconnected and the pseudorange correction information can not be generated in real time, the user position information calculation unit 150 calculates the user position information based on the observation received through the user GNSS observation data receiving unit 140 And calculates the current position information of the user using the data.

Since the user's current position information calculated at this time includes the above-described error, the user position information calculation unit 150 calculates the user's position using the past pseudorange correction information stored in the memory 160, So that the positional accuracy with respect to the user can be continuously maintained.

That is, if the reference station data can not be continuously received due to a communication failure with the reference station 200 or a communication disconnection, the pseudo range correction information reflected in the user position information of the user in the past and the current position information of the calculated user And calculates the position information of the user by reflecting the pseudo distance by the calculated GNSS position or by calculating the pseudo range correction reflected in the past user position information of the user, Distance information from the memory 160 and generates new pseudorange correction information through the averaging or median calculation of the extracted pseudorange correction information and reflects the new pseudorange correction information to the calculated pseudorange distance for each GNSS, Can be calculated.

Accordingly, even when the reference station data can not be received from the reference station 200 in real time, it is possible to maintain accurate position accuracy for the user.

3 is a flowchart illustrating a procedure for generating pseudo range correction information through a DGNSS pseudorange correction information generator according to an exemplary embodiment of the present invention and calculating position information of the user.

3, the procedure for generating the pseudorange correction information through the DGNSS pseudorange correction information generating apparatus and calculating the position information of the user may be performed by the user terminal 300 itself or the user terminal 300 The user GNSS observation data is received from the GNSS receiver located outside the user's home network (S111), and the pseudo distance for each GNSS is calculated based on the received user GNSS observation data (S112).

The calculated pseudoranges for each GNSS may include various errors such as ionospheric delay error, tropospheric delay error, and the like.

Simultaneously, the DGNSS pseudo distance correction information generating apparatus 100 receives the precise coordinates of the reference station 200 and the GNSS observation data from the reference station 200 in real time (S110).

The reference station 200 observes the same satellites as a plurality of GNSS satellites observed in a GNSS receiver provided in a user terminal. The reference station 200 observes the corresponding GNSS satellite data and the precise coordinates of the reference station 200 DGNSS pseudo range correction information generating apparatus 100 according to an embodiment of the present invention.

Also, the GNSS satellite includes GPS, GLONASS, Galieo, and Compass (Bader satellite), and the DGNSS pseudorange generator 100 generates pseudorange correction information for all GNSS satellites to calculate the location information of the user can do.

The observation data also includes satellite navigation information contained in the satellite navigation signal received from the GNSS satellite and the reception time of the satellite navigation signal received from the observed GNSS satellite.

The satellite navigation information may vary according to the type of the GNSS satellite, and the satellite navigation information according to the type of the GNSS satellite is already known, and thus a detailed description thereof will be omitted.

Next, the DGNSS pseudo distance correction apparatus 100 calculates position information of the reference station 200 using the GNSS observation data received from the reference station 200 (120).

The DGNSS pseudo distance correction information generating apparatus 100 calculates the pseudoranges for each GNSS based on the received GNSS topographic observation data and outputs the calculated pseudoranges to the corresponding base station 200 using the trilateration principle. As shown in FIG.

The position information of the reference station 200 calculated at this time is an approximate three-dimensional coordinate of the reference station 200 and includes error information due to various causes in the satellite navigation signal transmitted and received from the GNSS satellite .

 Next, the DGNSS pseudorange correction information generator 100 compares the calculated position information of the reference station 200 with the precise coordinates of the reference station 200 received from the reference station 200 , And generates pseudo distance correction information for an error value generated in the position information (130).

That is, the pseudo range correction information is not generated only in the reference station 200 like the conventional DGNSS, but is generated in the user terminal itself, and the load concentrated on the reference station 200 can be dispersed. To allow DGNSS operation to be performed at each user's terminal, thereby maintaining improved positional accuracy for the user.

Next, the generated pseudorange correction information is reflected in the GNSS pseudo distance calculated in step S112 to accurately calculate position information for the user (S140) and output to the user terminal 300, And provides the calculated position information.

Also, the DGNSS pseudo distance correction information generating apparatus 100 maps the calculated position information, reflected pseudo distance correction information, and identification information of the GNSS satellite included in the GNSS observation data received from the reference station 200, (160).

FIG. 4 is a block diagram showing a configuration of a DGNSS pseudorange correction information generating apparatus according to an embodiment of the present invention. Referring to FIG. 4, when the communication between the reference station and the DGNSS pseudorange correction information generating apparatus is poor or temporary communication is lost, FIG. 7 is a flowchart illustrating a procedure for calculating location information. FIG.

4, the procedure for calculating the location information of the user through the DGNSS pseudorange correction information generating apparatus 100 first receives user GNSS observation data from the GNSS receiver provided in the user terminal 300 itself or the outside (S210).

Next, using the received user GNSS observation data, the pseudo distance for each GNSS is calculated (S220).

Also, due to the influence of the surrounding environment depending on the user's location, the communication between the reference station and the DGNSS pseudorange correction information generating apparatus 100 is poor, or the reference station data can not be received in real time due to temporary communication interruption, (Step S230), the DGNSS pseudorange correction information generator 100 calculates the current position information of the user using the calculated pseudorange by GNSS ratio (S240).

The current location information of the user is performed by applying trilateration principles to pseudo-distances of at least four or more GNSS satellites to generate three-dimensional coordinates.

Next, at least one past pseudorange correction information stored in the memory 160 is extracted based on the calculated current position information of the user (S250).

The DGNSS pseudo distance correction information generating apparatus 100 observes the same satellite as the observed GNSS satellite to calculate the calculated current position information of the user from the memory 160 in order to extract past pseudorange correction information And retrieves past user location information generated by the user.

Thereafter, the DGNSS pseudorange correction information generator 100 searches the past user location information of the user who is nearest to the calculated current location information of the user, and stores the pseudo distance correction information And may be reflected in the pseudo distance according to the GNSS gender calculated in step S220.

At this time, the DGNSS pseudo distance correction information generating apparatus 100 searches for at least one past user position information that is closest to the calculated current position information of the user, The pseudo distance correction information may be extracted, the extracted pseudo distance correction information may be averaged, or new pseudo range correction information may be generated by calculating an intermediate value.

Next, the DGNSS pseudo range correction information generator 100 reflects the extracted pseudo range correction information to the calculated pseudo range of the GNSS, and calculates the position information of the user accurately (S260).

When a plurality of pseudorange correction information is extracted through step S250, the DGNSS pseudorange distance correction information generating apparatus 100 generates new pseudorange correction information by averaging or calculating a median value, It is possible to accurately calculate the user location information by reflecting on the distance.

On the other hand, when the communication between the reference station 200 and the DGNSS pseudo distance correction information generating apparatus 100 is good (S230), the DGNSS pseudorange distance correction information generating apparatus 100 receives (S241). The pseudo distance correction information generated based on the reference station data is reflected in the GNSS pseudo distance calculated in step S220, Information is calculated (S251).

The process of calculating the location information of the user through steps S241 and S251 is the same as the process of calculating the location information of the user with reference to FIG.

As described above, the DGNSS pseudorange correction information generator and the method thereof are capable of generating the pseudorange correction information by itself in the user terminal, thereby maintaining the improved position accuracy for the user.

In addition, it is possible to generate pseudo range correction information by itself in the user terminal, thereby distributing the load concentrated on the reference station, minimizing the cost of installation of the reference station, It is possible to provide more accurate position information to the user by providing the reference station of the base station at a plurality of locations and minimizing the distance between the reference station and the user.

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 disclosed exemplary embodiments. .

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 disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present invention.

100: DGNSS pseudo distance correction information generating apparatus 110: Reference station data receiving section
120: reference station position information calculation unit 130: pseudo distance correction information generation unit
140: User GNSS observation data receiving unit 150: User location information calculating unit
160: memory 200: reference station
300: user terminal

Claims (8)

A pseudo distance correction information generation unit that generates pseudo distance correction information based on reference station data received from a reference station in a user terminal;
A user GNSS observation data receiver for receiving user GNSS observation data from the user terminal; And
And a user location information calculation unit for calculating user location information from the pseudo range correction information and the received user GNSS observation data. The method according to claim 1,
Wherein the reference station data includes precise coordinates of a reference station and GNSS topographic observation data including a reception time at which a satellite navigation signal transmitted from a plurality of GNSS satellites is received at the reference station, And generates pseudo range correction information. The method of claim 2,
A reference station data receiver for receiving reference station data for a plurality of satellites from a reference station; And
And a reference station position information calculation unit for calculating position information of the reference station using the received observation data for GNSS status,
Wherein the pseudo distance correction information generation unit generates pseudo distance correction information by comparing the calculated position information with precision coordinates of the received reference station and calculating an error with respect to the calculated position information, DGNSS An apparatus for generating pseudorange correction information. The method according to claim 1,
Wherein the user location information calculation unit comprises:
Calculates pseudoranges for each GNSS on the basis of observation data for a plurality of GNSS satellites received through a GNSS receiver provided in the user terminal itself or externally, and calculates pseudorange correction information And calculates position information on the user based on the calculated DGNSS pseudorange correction information. A pseudo distance correction information generation step of generating pseudo distance correction information based on reference station data received from a reference station in a user terminal;
Receiving user GNSS observation data from the user terminal; And
And calculating user location information from the pseudo distance correction information and the received user GNSS observation data. The method of claim 1, further comprising: The method of claim 5,
Wherein the reference station data includes precise coordinates of a reference station and GNSS topographic observation data including a reception time at which a satellite navigation signal transmitted from a plurality of GNSS satellites is received at the reference station, A method for generating pseudo range correction information. The method of claim 6,
The method comprises:
A reference station data receiving step of receiving reference station data for a plurality of satellites from a reference station; And
And a reference station position information calculation step of calculating position information of the reference station using the received observation data for GNSS status,
Wherein the pseudo distance correction information generating step generates pseudo distance correction information by comparing the calculated position information with accurate coordinates of the received reference station and calculating an error with respect to the calculated position information, Method for generating DGNSS pseudorange correction information at a terminal The method of claim 5,
Wherein the user location information calculation step comprises:
Calculates the pseudoranges for each GNSS based on the observation data of a plurality of GNSS satellites received through the GNSS receiver installed in the user terminal or outside the GNSS receiver, And calculates position information for the user based on the calculated DGNSS pseudorange correction information.

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