JP2017015458A - Location conversion system, positioning terminal device and location conversion program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide means that reduces a displacement of a display location based on crustal movements when displaying a current location on an electronic map.SOLUTION: In a decimeter class positioning terminal device 100, a positioning calculation unit 130 is configured to calculate a current location 521, and a terminal side communication unit 170 is configured to transmit the current location 521 to a map acquisition server 200A. The map acquisition server 200A is configured to acquire a partial electronic map 531 serving as one part of an electronic map and including the current location 521 from a map distribution server 200B, and further acquire a crustal movement correction parameter 510 from a correction parameter generation server 200C to convert the current location 521 to a conversion location in an epoch coordinate, using the crustal movement correction parameter 510. The map acquisition server 200A is configured to transmit the conversion location 522 and the partial electronic map 531 to the decimeter class positioning terminal device 100, and the decimeter class positioning terminal device 100 is configured to display the partial electronic map 531, and display the conversion location 522 on the partial electronic map 531.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a position conversion system that converts a measured current position, a positioning terminal device that converts a positioned current position, and a position conversion program that converts a positioned current position.

  Conventionally, there is a technique for transmitting positioning reinforcement information from a positioning reinforcement information generating apparatus on the center side to a GNSS (Global Navigation Satellite Systems) receiver on the user side (for example, Patent Document 1).

Japanese Patent No. 5570649

  It is desirable for the user side to obtain a highly accurate positioning result. However, on the user side, there is a demand for a positioning process that can obtain a moderate accuracy even if the accuracy is lower than that of the high-accuracy positioning, and has a lower processing load than the high-accuracy positioning.

  In addition, when displaying the current position as a positioning result on the electronic map, the coordinates change due to subsequent crustal movement at the time when the electronic map was created, and when the current position is displayed on the electronic map, May shift.

The present invention reduces the displacement of the display position based on crustal movement when displaying the current position on the electronic map, and accurately and efficiently displays the user position on the electronic diagram displayed on the screen of the user terminal device. It aims at providing the means to do.
It is another object of the present invention to suck up a user request associated with the user's position from the user terminal device and efficiently provide the user with location-related information that matches the user request.

The position conversion system of this invention is
A position conversion system comprising a positioning terminal device and a position conversion device,
The positioning terminal device
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal side communication unit for transmitting the current position;
A terminal side display,
A terminal-side display processing unit,
The position conversion device includes:
A conversion side receiving unit for receiving the current position;
When the current position is received, a conversion-side map acquisition unit that acquires a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
When the current position is received, the conversion parameter is obtained from a providing device that provides a conversion parameter used to convert the current position into the original period coordinates, and the current position is determined using the conversion parameter. A conversion side conversion unit for converting to the original period coordinates;
A conversion side transmission unit that transmits the partial electronic map and the conversion position that is the current position converted into the original period coordinates to the positioning terminal device;
The terminal side communication unit
Receiving the partial electronic map and the converted position;
The terminal-side display processing unit
The partial electronic map is displayed on the terminal side display unit, and the conversion position is displayed on the partial electronic map.

The conversion parameter is:
Based on the measurement position coordinates of the electronic reference point measured after the original period of the electronic map and the original position coordinates of the electronic reference point in the electronic map, it is generated as information reflecting crustal movement. .

The conversion parameter is:
It is generated as a coefficient of a Chebyshev function that is a multi-dimensional two-dimensional collocation orthogonal polynomial.

The conversion parameter is:
The measurement position coordinate of the electronic reference point is generated as a component of a matrix for converting the original reference position coordinate of the electronic reference point.

The terminal side communication unit
Along with the current location, send a user request to request acquisition of location related information related to the current location,
The conversion side receiver is
Receiving the user request with the current location;
The position conversion device further includes:
A search-side storage unit that searches for the position-related information that the user request requests acquisition and stores the search result, the user request, and the conversion position in a database device in association with each other.
The conversion side transmitter is
The search result of the position related information is transmitted to the positioning terminal device.

The terminal side positioning unit is
The current position is calculated by using the second positioning reinforcement information obtained by degrading the first positioning reinforcement information used for correcting the positioning error together with the positioning signal.

The positioning terminal device of this invention
A positioning terminal device that measures the current position,
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal side communication unit that transmits the current position to a position conversion device that converts the current position;
A terminal side display,
A terminal-side display processing unit,
The terminal side communication unit
By communicating with the position conversion device,
Causing the position conversion device to acquire a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
Causing the position conversion device to acquire the conversion parameter from a providing device that provides a conversion parameter used to convert the current position to the original period coordinate;
The position conversion device, using the conversion parameter to convert the current position to the original coordinates,
The position conversion device, the partial electronic map and the conversion position that is the current position converted to the original period coordinates,
Receiving the partial electronic map and the conversion position transmitted to the position conversion device;
The terminal-side display processing unit
The partial electronic map is displayed on the terminal side display unit, and the conversion position is displayed on the partial electronic map.

The position conversion program of this invention is
On the computer,
The process of calculating the current position using the positioning signal transmitted from the satellite,
A process of transmitting the current position to a position conversion device that converts the current position;
By communicating with the position conversion device,
Processing for acquiring a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original coordinates to the position conversion device;
A process for causing the position conversion device to acquire the conversion parameter from a providing device that provides a conversion parameter used to convert the current position to the original period coordinate;
Processing for converting the current position to the original coordinate using the conversion parameter for the position conversion device,
Processing for transmitting the partial electronic map and the converted position which is the current position converted into the original period coordinates to the position converting device;
Processing for receiving the partial electronic map and the conversion position transmitted to the position conversion device;
A process of displaying the partial electronic map and displaying the conversion position on the partial electronic map is executed.

The positioning terminal device of this invention
A positioning terminal device that measures the current position,
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal-side map acquisition unit that acquires a partial electronic map including the current position among the electronic map from a distribution device that distributes the electronic map generated using the original period coordinates;
A terminal-side conversion parameter acquisition unit that acquires the conversion parameter from a providing device that provides a conversion parameter used to convert the current position into the original period coordinate;
A terminal side conversion unit that converts the current position into the original period coordinates using the conversion parameter;
A terminal side display,
A terminal-side display processing unit that displays the partial electronic map on the terminal-side display unit and displays the converted position that is the current position converted into the original period coordinates on the partial electronic map.

The position conversion program of this invention is
On the computer,
The process of calculating the current position using the positioning signal transmitted from the satellite,
Processing for obtaining a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
Processing for obtaining the conversion parameter from a providing device that provides a conversion parameter used for converting the current position into the original period coordinate;
A process of converting the current position to the original coordinate using the conversion parameter;
Processing for displaying the partial electronic map and displaying the converted position which is the current position converted to the original period coordinates on the partial electronic map;
Is executed.

The present invention converts the current position into the original period coordinates in the original period of the electronic map, and displays the converted position on the electronic map having the original period, thereby reducing the displacement of the display position based on the crustal movement. The user position can be accurately and efficiently displayed on the electronic diagram displayed on the screen of the user terminal device.
In addition, the present invention can absorb a user request associated with the user's position from the user terminal device and efficiently provide the user with position-related information that matches the user request.

FIG. 3 is a diagram of the first embodiment and shows a position conversion system 1000. FIG. 3 is a diagram of the first embodiment and includes a block diagram of the decimator class positioning terminal device 100. FIG. 3 is a diagram of the first embodiment, and is a block diagram of a decimator class positioning reinforcement information generation device 300. FIG. 3 is a diagram of the first embodiment, and is a sequence diagram illustrating an operation of the position conversion system 1000. The figure of Embodiment 1 is a figure which shows the calculation method by the matrix of a crustal movement conversion parameter. The figure of Embodiment 1, The figure which shows the calculation method by the Chebyshev function of the crustal movement correction parameter. The figure of Embodiment 1 is a figure which shows conversion to the conversion position of the present position using the crustal movement correction parameter 510 calculated | required by the Chebyshev function. FIG. 3 is a diagram of the first embodiment, and shows a display screen of the decimator class positioning terminal device 100. The figure of Embodiment 1, The figure which shows the modification of the decimator class positioning terminal device 100. FIG. FIG. 5 is a diagram of the second embodiment, and is a block diagram of a decimator class positioning reinforcement information generation device 300-1. The figure of Embodiment 2, The figure containing the block diagram of the decimator class positioning terminal device 100-1. FIG. 10 is a diagram of the second embodiment, and is a sequence diagram illustrating an operation of the position conversion system 1000-1. FIG. 10 shows the hardware configuration of the decimator-class positioning terminal device 100 in the third embodiment.

Embodiment 1 FIG.
A position conversion system 1000 according to the first embodiment will be described with reference to FIGS.
In addition, the electronic map demonstrated by the following embodiment is an electronic map produced | generated using the original period coordinate. In the following description, it is assumed that this electronic map is provided by the Geospatial Information Authority of Japan, but an electronic map provided by other than the Geospatial Information Authority of Japan may be used as long as it is generated using original coordinates. Further, an electronic map based on a past position other than the original period may be used. At that time, conversion from the current coordinates to the position at a certain time in the past when the electronic map was created is performed, and the concept of the present invention is not affected.

<*** Explanation of configuration *****>
FIG. 1 is a diagram showing a position conversion system 1000. In the position conversion system 1000, the centimeter class positioning reinforcement information generation device 20 obtains the centimeter class positioning reinforcement information 610 in real time, and the decimator class positioning reinforcement information generation apparatus 300 generates the decimator class positioning reinforcement information 620. Distribution is made to the user using the public Wi-Fi network 81. The user obtains the current position 521 in real time using a GNSS positioning signal 541 such as GPS and the decimator class positioning reinforcement information 620. The decimator class positioning terminal device 100 is characterized in that the current position calculated by the decimator class positioning terminal device 100 is sent to a map acquisition server 200A, which will be described later with reference to FIG. 2, and the map acquisition server 200A converts the current position into original coordinates, The later conversion position is returned to the decimator class positioning terminal device 100 together with the partial electronic map 531 which is a part of the electronic map.

  As shown in FIG. 1, the decimator class positioning terminal device 100 includes an electronic reference point 10, a centimeter class positioning reinforcement information generation device 20, a main control station 30, a tracking control station 40, a quasi-zenith satellite 50, and GPS satellites 61 and 62. A centimeter class positioning terminal 70, a public Wi-Fi network 81, the Internet 82, a decimator class positioning terminal apparatus 100, a web server 200, and a decimator class positioning reinforcement information generating apparatus 300.

  FIG. 2 is a diagram including a block diagram of the decimator class positioning terminal device 100. FIG. 2 shows a block configuration of the decimator-class positioning terminal device 100, the map acquisition server 200A, the map distribution server 200B, and the correction parameter generation server 200C. Although the correction parameter generation server 200C is not connected to the Internet 82 in FIG. 2, the map acquisition server 200A to the correction parameter generation server 200C are actually connected to the Internet 82. The database device 200D is connected to the Internet 82. The decimator class positioning terminal device 100 communicates with the map acquisition server 200A via the Internet 82, and communicates with the decimator class positioning reinforcement information generation device 300 via the public Wi-Fi network 81. The map acquisition server 200A communicates with the map distribution server 200B via the Internet 82 and communicates with the correction and correction parameter generation server 200C.

  The decimator class positioning reinforcement information generation apparatus 300 acquires the centimeter class positioning reinforcement information 610 from the centimeter class positioning reinforcement information generation apparatus 20. The centimeter class positioning reinforcement information generation device 20 acquires electronic reference point information from the electronic reference point.

  As illustrated in FIG. 2, the position conversion system 1000 includes a decimator-class positioning terminal device 100 that is a positioning terminal device 8100 and a map acquisition server 200A that is a position conversion device 8200A.

  Decimator class positioning terminal device 100 is an integrated portable terminal device. Decimator-class positioning terminal device 100 that is positioning terminal device 8100 includes terminal-side positioning unit 101, terminal-side communication unit 170, display 190 that is terminal-side display unit 8190, and web browser execution unit 180 that is terminal-side display processing unit 8180. Prepare. The terminal-side positioning unit 101 calculates the current position 521 using the positioning signal 541 transmitted from the satellite. The terminal-side communication unit 170 transmits the current position 521 to the map acquisition server 200A that is the position conversion device 8200A.

  The terminal side positioning unit 101 uses the positioning signal 541 and the second positioning reinforcement information 8620 obtained by degrading the centimeter-class positioning reinforcement information 610 that is the first positioning reinforcement information 8610 used for correcting the positioning error. A certain decimator class positioning reinforcement information 620 is used to calculate the current position 521.

The map acquisition server 200A that is the position conversion device 8200A includes a receiving unit 212A that is the conversion-side receiving unit 8212A, a map assembly unit 220A that is the conversion-side map acquisition unit 8220A, a crustal movement correction unit 230A that is the conversion-side conversion unit 8230A, and a conversion A transmission unit 211A that is a side transmission unit 8211A and a storage unit 240A that is a conversion side storage unit 8240A.
(1) The receiving unit 212A receives the current position 521.
(2) When the current position 521 is received, the map assembling unit 220A receives the current position of the electronic map from the map distribution server 200B, which is the distribution device 8200B that distributes the electronic map generated using the original period coordinates. A partial electronic map 531 including 521 is acquired.
(3) The crustal movement correction unit 230A provides a crustal movement correction parameter 510 that is a conversion parameter 8510 used for conversion of the current position 521 to the original period coordinates when the current position 521 is received. A crustal movement correction parameter 510 is acquired from a certain correction parameter generation server 200C. Then, the crustal movement correction unit 230A converts the current position 521 to the original coordinates using the crustal movement correction parameter 510.
(4) The transmission unit 211A that is the conversion-side transmission unit 8211A transmits the partial electronic map 531 and the conversion position 522 that is the current position 521 converted into the original period coordinates to the decimator-class positioning terminal device 100.

  The terminal-side communication unit 170 of the decimator class positioning terminal device 100 receives the partial electronic map 531 and the conversion position 522. The web browser execution unit 180 of the decimator class positioning terminal device 100 displays the partial electronic map 531 on the display 190 and displays the conversion position 522 on the partial electronic map 531.

  Note that the terminal-side communication unit 170 transmits a user request 524 requesting acquisition of position-related information 523 related to the current position 521 together with the current position 521. The receiving unit 212A, which is the conversion-side receiving unit 8212A, receives the user request 524 together with the current position 521. The storage unit 240A, which is the conversion-side storage unit 8240A, searches the location-related information 523 requested by the user request 524 via the Internet 82, and associates the search result with the user request 524 and the conversion position 522 to create a database device. Accumulate in 200D. The storage unit 240A, which is the conversion-side storage unit 8240A, transmits the search result of the position related information to the decimator class positioning terminal device 100 via the transmission unit 211A and notifies the user of the search result.

  FIG. 2 will be specifically described. First, the configuration of the decimator class positioning terminal device 100 will be described. The decimator class positioning terminal device 100 includes a GNSS positioning signal antenna 110, a GNSS receiving unit 120, a terminal side positioning unit 101, a battery 160, a terminal side communication unit 170, a web browser execution unit 180, and a display 190.

  The GNSS positioning signal antenna 110 receives positioning signals 541 from the quasi-zenith satellite 50 and the GPS satellites 61 and 62. The GNSS receiving unit 120 is a receiving unit that receives a positioning signal via the GNSS positioning signal antenna 110. The terminal side positioning unit 101 is connected to the maintenance personal computer 400. The terminal-side positioning unit 101 includes a positioning calculation unit 130, a Wi-Fi adapter 140, and a decoder 150. The Wi-Fi adapter 140 receives decimator class positioning reinforcement information 620 from the public Wi-Fi network 81. The decoder 150 decodes the decimator class positioning reinforcement information 620 received by the Wi-Fi adapter 140. The positioning calculation unit 130 measures the current position 521 using the positioning signal received by the GNSS receiving unit 120 and the decimator class positioning reinforcement information 620 decoded by the decoder 150.

  The terminal-side communication unit 170 transmits the current position 521 to the map acquisition server 200A, and receives the partial electronic map 531 and the conversion position 522 transmitted from the map acquisition server 200A.

  The web browser execution unit 180 displays the partial electronic map 531 received by the terminal side communication unit 170 on the display 190, and displays the conversion position 522 received by the terminal side communication unit 170 on the partial electronic map 531.

The map acquisition server 200A includes a transmission unit 211A, a reception unit 212A, a map assembly unit 220A, a crustal movement correction unit 230A, and a storage unit 240A. The transmission unit 211A transmits information to the decimator class positioning terminal device 100. The receiving unit 212A receives information from the decimator class positioning terminal device 100. The map assembly unit 220A acquires a partial electronic map 531 that is a part of the electronic map from the map distribution server 200B. The crustal movement correction unit 230A acquires a crustal movement correction parameter 510, which will be described later, from the correction parameter generation server 200C, converts the current position received from the decimator class positioning terminal device 100 into the position of the original coordinate, and the current position 521. From this, a conversion position 522 is generated. The accumulating unit 240A retrieves the position related information 523 requested by the user request 524 via the Internet 82, and accumulates the search result, the user request 524, and the conversion position 522 in association with each other in the database device 200D. The storage unit 240A transmits the search result of the position related information to the decimator class positioning terminal device 100 via the transmission unit 211A, and notifies the user of the search result.
To do.

  The map distribution server 200B is a device that distributes an electronic map. The map distribution unit 210B distributes the partial electronic map 531.

  In the correction parameter generation server 200C, the crustal movement correction parameter generation unit 210C transmits the crustal movement correction parameter 510 to the crustal movement correction unit 230A in response to a request from the crustal movement correction unit 230A of the map distribution server 200B.

  In the database apparatus 200D, the search result, the user request 524, and the conversion position 522 are stored in association with each other by the storage unit 240A of the map acquisition server 200A.

  FIG. 3 is a block diagram of the decimator class positioning reinforcement information generation device 300. The decimator class positioning reinforcement information generating apparatus 300 will be described with reference to FIG. Decimator-class positioning reinforcement information generation device 300 receives centimeter-class positioning reinforcement information, navigation message, electronic reference point current position, and status from centimeter-class positioning reinforcement information generation device 20 via external I / F 350. Get etc. These pieces of information are stored in the centimeter class positioning reinforcement information storage area 311, the navigation message storage area 312, the environment setting parameter storage area 313, and the electronic reference point data storage area 314 of the storage unit 310.

  Decimator class message generator 320 extracts a part of information from centimeter class positioning reinforcement information 610 to generate decimator class positioning reinforcement information 620. Decimator-class positioning reinforcement information 620 is generated from centimeter-class positioning reinforcement information 610 by thinning out the number of grids for spatially dependent correction amounts such as ionospheric delay information and tropospheric delay information. A small correction amount is generated by thinning out the time. The decimator class reinforcement information evaluation unit 330 evaluates the generated decimator class positioning reinforcement information 620. The supervising unit 340 supervises the processing by the decimator class positioning reinforcement information generating device 300. The external I / F 350 delivers decimator class positioning reinforcement information 620 from the public Wi-Fi network 81.

<*** Explanation of operation *****>
The operation of the position conversion system 1000 will be described with reference to FIG. 4 showing the operation of the position conversion system 1000-1.

  In step S <b> 11, in the decimator class positioning reinforcement information generation device 300, the external I / F 350 acquires the centimeter class positioning reinforcement information 610 from the centimeter class positioning reinforcement information generation device 20.

  In step S12, in the decimator class positioning reinforcement information generating apparatus 300, the decimator class message generating unit 320 generates decimator class positioning reinforcement information 620 from the centimeter class positioning reinforcement information 610, and the external I / F 350 has the decimator class positioning reinforcement information 620. Is distributed via the public Wi-Fi network 81.

In step S13, in the decimator class positioning terminal device 100, the positioning calculation unit 130 determines the current position 521 using the decimator class positioning reinforcement information 620 decoded by the decoder 150 and the positioning signals of the GPS satellite and the quasi-zenith satellite. Generate.
In step S14, the terminal-side communication unit 170 transmits the current position 521 generated by the positioning calculation unit 130 to the map acquisition server 200A.

In step S15, when the receiving unit 212A of the map acquisition server 200A receives the current position 521, the map assembling unit 220A is a part of the electronic map generated using the original period coordinates from the map distribution server 200B. A partial electronic map 531 is acquired.
In step S <b> 16, the map assembling unit 220 </ b> A acquires a partial electronic map 531 including the current position 521. The map assembly unit 220A has an electronic map reconstruction function.
In step S17, the map assembling unit 220A reconstructs the acquired partial electronic map 531. The reconstruction of the partial electronic map 531 is to adjust the scale, resolution, etc. of the partial electronic map 531.

  In step S18, the crustal movement correction unit 230A requests the crustal movement correction parameter 510 from the correction parameter generation server 200C.

  In step S19, in the crustal movement correction parameter generation unit 210C of the correction parameter generation server 200C, the crustal movement correction parameter generation unit 210C generates the crustal movement correction parameter 510. The crustal movement correction parameter 510 which is the conversion parameter 8510 includes the measurement position coordinates 551 of the electronic reference point measured after the original period of the electronic map provided by the Geographical Survey Institute and the original position of the electronic reference point in the electronic map. Based on the coordinates 550, it is generated as information reflecting the crustal movement.

Here, two types of generation methods for the crustal movement correction parameter 510 will be described.
FIG. 5 is a diagram illustrating a first generation method using a matrix. The crustal movement correction parameter 510 is information for converting the current position 521 generated by the decimator class positioning terminal device 100 to the position of the original period coordinates, and the current position of the original period and the electronic reference point in the electronic map. It is information for reflecting the crustal movement between the current position and the positioning position.
Specifically, when the current position 521 generated by the decimator class positioning terminal device 100 is displayed on the electronic map provided by the Geographical Survey Institute, the position is shifted due to the influence of crustal movement. Therefore, information for returning the current position 521 to the original time point is the crustal movement correction parameter 510.

FIG. 5 shows a conversion formula from the current position (x _1i , x _2i , x _3i ) of the electronic reference point P to the original period coordinate values (y _1i , y _2i , y _3i ). i is the number of samples.
In FIG. 5, the original position coordinates 550 on the electronic map of the electronic reference point P are (y _1i , y _2i , y _3i ), and are measured after the original period of the electronic map of the electronic reference point P. Assume that the measurement position coordinates 521 are (x _1i , x _2i , x _3i ).
In this case, the crustal movement correction parameter 510 is obtained as a component a _ij of the matrix 560 that converts the measurement position coordinate 521 of the electronic reference point P into the original position coordinate 550 of the electronic reference point P. By multiplying the matrix 560 by the coordinates (x _1i , x _2i , x _3i ) of the current position 521 and adding (x _1cnst , x _2cnst , x _3cnst ), which is a constant term 561, as in (Formula A). , (Y _1i , y _2i , y _3i ) of the original position coordinates 550 can be obtained.
Specifically, as shown in FIG. 5, (Formula A) is modified as (Formula B), and the relationship of n sample points is substituted into (Formula B). [A _kl ] which is the matrix 560 is obtained.
Summarizing (Formula B),
Y = AX
It expresses.
Here, a matrix of the coefficient A is obtained by the least square method.
A = (X ^T X) ⁻¹ (X ^T Y)
The matrix A is obtained as follows.
There are several methods for solving the coefficient solution as follows. When the matrix (X ^T X) that solves the normal equation with an inverse matrix is a regular matrix (that is, full rank), the solution A is uniquely obtained. However, the inverse matrix of (X ^T X) may be numerically unstable. Therefore, as a method with a small amount of calculation, there is a method of solving by using triangular matrix decomposition by Cholesky decomposition (X ^T X = R ^T R, R is an m × m upper triangular matrix). As a numerically stable and general-purpose method, there is a method using QR decomposition or singular value decomposition (SVD). These methods have high numerical stability because they do not require a product (X ^T X) in the course of calculation. Further, when (X ^T X) is not a regular matrix (decreasing rank), the solution of the normal equation is indefinite, but even in this case, it is possible to obtain the solution having the smallest norm among the solutions a. it can.
Note that the crustal movement correction parameter generation unit 210C can acquire the measurement position coordinates 551 of the electronic reference point P from the centimeter class positioning reinforcement information generation apparatus 20, and the original period position coordinates can be acquired from the map distribution server 200B.

Next, a second generation method of the crustal movement correction parameter 510 will be described.
FIG. 6 is a diagram illustrating a second generation method using a two-dimensional Chebyshev polynomial.

<1. Step of obtaining crustal deformation correction polynomial>
In this step, the coefficient of the crustal deformation correction polynomial is obtained from the current coordinate value (F3 value) of the electronic reference point used in the centimeter class positioning reinforcement system and the original coordinate value corresponding to each obtained from the Geospatial Information Authority of Japan. It is. Therefore, the same polynomial is used until the current coordinate value (F3 value) of the electronic reference point used in the centimeter class positioning reinforcement system is changed. The coefficient of the crustal movement correction polynomial obtained here corresponds to the crustal movement correction parameter 510.
The current position coordinates of the n electronic reference points are (ξ ₁₁ , ξ ₂₁ , ξ ₃₁ ), (ξ ₁₂ , ξ ₂₂ , ξ ₃₂ )... (ξ _1n , ξ _2n , ξ _3n ).
The original position coordinates with respect to the current position coordinates of each electronic reference point are (y ₁₁ , y ₂₁ , y ₃₁ ), (y ₁₂ , y ₂₂ , y ₃₂ )... (Y _1n , y _2n , y _3n ) To do.
Here, the r-th order crustal movement correction polynomial for converting from horizontal coordinates to the original coordinates is defined as follows.

T _kl (x) represents a two-dimensional Chebyshev polynomial (collocated orthogonal polynomial). In addition, the third to fifth orders are appropriate for the correlation between the conversion accuracy and the calculation processing load.
By the least square method, the best coefficient β ^* _r that minimizes the error is obtained as follows.

Current coordinate x = (x ₁ , x ₂ ) (Formula 3)
Current coordinate value (electronic reference point coordinate value): ξ _i
ξ _i = (ξ _1i , ξ _2i ), (i = 1, 2,... n) (Formula 4)
T _kl (x ₁ , x ₂ ) = T _k (x ₁ ) T _l (x ₂ )
(K ≧ 0, l ≧ 0, k + l ≦ r) (Formula 5)
The coefficient β ^* _r is obtained in advance, and similar terms are put together to obtain the following equation 6, and β ₀ ,... Β _r in equation 6 are used as the crustal deformation correction parameter 510.
y _r (x) = β ₀ + β ₁ x + β ₂ x ² +... + β _r x ^r (Formula 6)
In the example of the second generation method, an example of the Chebyshev polynomial is shown, but the same effect can be obtained even if a Legendre polynomial, a Lagrange polynomial, or the like is used as the orthogonal polynomial. Further, as an interpolation method, spline interpolation may be used.

<2. Step to convert current position to original period coordinates>
With reference to FIG. 7, the step of converting from the current coordinate value of the user to the original coordinate value using the crustal movement correction polynomial will be described.
FIG. 7 is a diagram illustrating a step of converting the current coordinate value of the user from the original coordinate value using the crustal movement correction polynomial. This step is executed by the crustal movement correction unit 230A that has received the crustal movement correction parameter 510. This step converts the current coordinate value of the user measured by the user into the original coordinate value corresponding to the coordinate system of the partial electronic map, using the crustal deformation correction polynomial obtained in step 1 above to obtain the crustal deformation correction polynomial. To do.
As shown in FIG. 7, each current coordinate value is obtained by using the crustal movement correction polynomial yrm (x) of FIG. 7 that converts the current horizontal coordinate (ξ _1u , ξ _2u ) of the user into each axis of the original period coordinate. The original coordinate values (y _r1u , y _r2u , y _r3u ) corresponding to are obtained.

  Next, in step S20, the crustal movement correction parameter generation unit 210C transmits the generated crustal movement correction parameter 510 to the map acquisition server 200A.

In step S21, the crustal movement correction unit 230A of the map acquisition server 200A uses the received crustal movement correction parameter 510 to generate a converted position 522 obtained by converting the current position 521 into the original coordinates. The transmission unit 211A of the map acquisition server 200A transmits the partial electronic map 531 acquired from the map distribution server 200B and the conversion position 522 converted using the crustal movement correction parameter 510 to the decimator class positioning terminal device 100.
When the map acquisition server 200A receives the next current position from the decimator-class positioning terminal device 100 within the set time, the map acquisition server 200A does not acquire the partial electronic map 531 but only the converted position obtained by converting the received current position. It returns to the decimator class positioning terminal device 100.

In step S <b> 22, in the decimator class positioning terminal device 100, the terminal side communication unit 170 receives the partial electronic map 531 and the conversion position 522. The web browser execution unit 180 displays the partial electronic map 531 on the display 190 and displays the conversion position 522 on the partial electronic map 531.
FIG. 8 shows a display screen on the display 190 by the web browser execution unit 180.
A series of black circles is a plot display of the current location. In this way, the web browser execution unit 180 has a locus plot display function. Further, the web browser execution unit 180 also performs landmark display 701 of the Wi-Fi spot as shown in FIG.

<*** Explanation of effects *****>
As described above, since the decimator-class positioning terminal device 100 displays the converted position 522 converted into the original period coordinates on the partial electronic map 531, the positioning position can be displayed in a consistent state on the electronic map. Further, since the decimator class positioning terminal device 100 does not execute the process of obtaining the crustal movement correction parameter 510, the load on the decimator class positioning terminal device 100 can be suppressed.

<*** Other configurations *****>
With reference to FIG. 9, the decimator class positioning terminal device which is a modification of the decimator class positioning terminal device 100 in Embodiment 1 is demonstrated.
FIG. 9 is a diagram for explaining a decimator class positioning terminal device. The decimator-class positioning terminal device 100 shown in FIG. 2 assumes an integrated portable terminal device. The decimator-class positioning terminal device of FIG. 9 is a terminal-side positioning unit 101 that is a decimator-class positioning terminal device, and is a device separate from the display terminal device 102 that includes the terminal-side communication unit 170, web browser execution unit 180, and display 190. It is. The display terminal device 102 is a smartphone, and the decimator-class positioning terminal device corresponds to a positioning adapter connected to the smartphone. The decimator-class positioning terminal device transmits the current position 521 to the terminal side communication unit 170. The processing after transmission is the same as that of the decimator class positioning terminal device 100.

  Since the decimator class positioning terminal device is a separate device that can be connected to the display terminal device 102, a user who desires the function of the decimator class positioning terminal device can use the display terminal device 102 as a positioning adapter. .

Embodiment 2. FIG.
A position conversion system 1000-1 according to the second embodiment will be described with reference to FIGS. Description of the same parts as those in the first embodiment is omitted, and different parts will be described. The position conversion system 1000-1 according to the second embodiment includes the decimator class positioning reinforcement information 620 in which the decimator class reinforcement information generation apparatus 300-1 generates the crustal movement correction parameter 510 and degrades the centimeter class positioning reinforcement information 610. The crustal movement correction parameter 510 is distributed via the public Wi-Fi network 81. The decimator-class positioning terminal device 100-1 receives the crustal movement correction parameter 510 from the public Wi-Fi network 81, the terminal-side positioning unit 101 calculates the current position 521, and the crustal movement correction parameter from the current position 521. 510 is used to generate a transform location 522. As described above, in the second embodiment, the function of the correction parameter generation server 200C of the first embodiment is included in the decimator class positioning reinforcement information generation apparatus 300-1, and the function of the crustal movement correction unit 230A is the decimator class positioning terminal apparatus 100-. 1 has.

FIG. 10 is a block diagram of the decimator class positioning reinforcement information generation device 300-1.
FIG. 11 is a block diagram of the decimator class positioning terminal device 100-1.
FIG. 12 is a sequence diagram showing the operation of the position conversion system 1000-1.

With reference to FIG. 10, decimator class positioning reinforcement information generating apparatus 300-1 having a function of generating crustal movement correction parameter 510 will be described. As shown in FIG. 10, the decimator class positioning reinforcement information generation device 300-1 further includes a crustal movement correction parameter storage area 315 that stores a crustal movement correction parameter 510, an electronic device, and the decimator class positioning reinforcement information generation device 300. An original period coordinate storage area 316 for storing the original period coordinates of the reference point is provided.
The decimator class message generating unit 320 uses the original period coordinates of the electronic reference point stored in the original period coordinate storage area 316 and the current position coordinates of the electronic reference point stored in the electronic reference point data storage area 314. Then, the crustal movement correction parameter 510 is calculated by the first generation method or the second generation method of the first embodiment. The external I / F 350 distributes the crustal movement correction parameter 510 and the decimator class positioning reinforcement information 620 generated by the decimator class message generation unit 320 via the public Wi-Fi network 81.

  Next, the decimator-class positioning terminal device 100-1 will be described with reference to FIG. As shown in FIG. 11, the decimator class positioning terminal device 100-1 further includes a terminal-side map acquisition unit 155 with respect to the decimator class positioning terminal device 100. In the decimator class positioning terminal device 100-1, the terminal-side positioning unit 101 has a crustal movement correction function in addition to the positioning function. This crustal movement correction function is the same as the function of the crustal movement correction unit 230A of the map acquisition server 200A.

  The Wi-Fi adapter 140 that is the terminal side conversion parameter acquisition unit 8140 is a decimator class reinforcement information generation device 300-that is a providing device 8300 that provides a crustal movement correction parameter 510 that is used to convert the current position 521 to the original coordinate. From 1, the conversion parameter 8510 is obtained. In addition to the function of the positioning unit, the terminal-side positioning unit 101-1 also has a function of a terminal-side conversion unit 8130 that converts the current position 521 to the original period coordinates using the crustal movement correction parameter 510. Decimator-class positioning terminal device 100-1 which is positioning terminal device 8100-1 has terminal-side map acquisition unit 155. The terminal-side map acquisition unit 155 sends a partial electronic map 531 including the current position 521 in the electronic map from the map distribution server 200B that distributes the electronic map generated using the original period coordinates via the map acquisition server 200A. get. The web browser execution unit 180 displays the partial electronic map 531 on the display 190, and displays the conversion position 522 that is the current position 521 converted into the original period coordinates on the partial electronic map 531.

With reference to FIG. 12, operation | movement of the decimator class positioning terminal device 100-1 is demonstrated.
Step S11 is the same as that in the first embodiment.
In step S12, the decimator class message generation unit 320 of the decimator class positioning reinforcement information generation apparatus 300-1 generates the decimator class positioning reinforcement information 620 and the crustal movement correction parameter 510, and the external I / F 350 receives the public Wi-Fi network 81. To deliver through.

  In the decimator class positioning terminal device 100-1, the Wi-Fi adapter 140 receives the decimator class positioning reinforcement information 620 and the crustal movement correction parameter 510. The decoder 150 decodes the decimator class positioning reinforcement information 620 and the crustal movement correction parameter 510.

Step S13 is the same as that in the first embodiment.
In step S <b> 13-1, the terminal side positioning unit 101 converts the current position 521 to the conversion position 522 using the received crustal movement correction parameter 510. As the conversion method, the method described in the first generation method or the second generation method of the crustal deformation correction parameter 510 is used.

  In step S14-1, the terminal-side communication unit 170 transmits a map request for requesting the partial electronic map 531 to the map acquisition server 200A and the conversion position 522.

  In steps 15 to S17, the map assembling unit 220A of the map acquisition server 200A acquires the partial electronic map 531 and transmits the partial electronic map 531 to the decimator-class positioning terminal device 100-1. This partial electronic map 531 is a map including a current position 521 and a conversion position 522. The following steps are the same as those in the first embodiment.

  In the decimator-class positioning terminal device 100-1 according to the second embodiment, since the terminal-side positioning unit 101 calculates the conversion position, the conversion position can be obtained quickly. Further, when the conversion position is continuously displayed on the partial electronic map 531 once acquired, there is an effect that communication with the map acquisition server 200A becomes unnecessary.

  In the case of Embodiment 1 and Embodiment 2 as well, the partial electronic map includes both the current position and its converted position.

Embodiment 3 FIG.
A hardware configuration example of the decimator class positioning terminal device 100 will be described with reference to FIG. Decimator-class positioning terminal device 100 is a computer.

  The decimator class positioning terminal device 100-1, the map acquisition server 200A, the map distribution server 200B, the correction parameter generation server 200C, the database device 200D, and the decimator class positioning reinforcement information generation devices 300 and 300-1 are also computers, and the decimator class The description of the positioning terminal device 100 applies to these devices.

  The decimator-class positioning terminal device 100 includes hardware such as a processor 901, an auxiliary storage device 902, a memory 903, a communication device 904, an input interface 905, and a display interface 906. The processor 901 is connected to other hardware via the signal line 910, and controls these other hardware. The input interface 905 is connected to the input device 907. The display interface 906 is connected to the display 908.

  The processor 901 is an IC (Integrated Circuit) that performs processing. The processor 901 is a CPU (Central Processing Unit), a DSP (Digital Signal Processor), a GPU (Graphics Processing Unit), or the like. The auxiliary storage device 902 is a ROM (Read Only Memory), a flash memory, an HDD (Hard Disk Drive), or the like. The memory 903 is a RAM (Random Access Memory). The communication device 904 includes a receiver 9041 that receives data and a transmitter 9042 that transmits data. The communication device 904 is a communication chip or a NIC (Network Interface Card). The input interface 905 is a port to which the cable 911 of the input device 907 is connected. The input interface 905 may be a USB (Universal Serial Bus) terminal. The display interface 906 is a port to which the cable 912 of the display 908 is connected. The display interface 906 may be a USB terminal or a HDMI (registered trademark) (High Definition Multimedia Interface) terminal. The input device 907 is a mouse, a keyboard, a touch panel, or the like. The display 908 is an LCD (Liquid Crystal Display).

The auxiliary storage device 902 includes the terminal-side positioning unit 101, the terminal-side communication unit 170, and the web browser execution unit 180 (hereinafter, the terminal-side positioning unit 101, the terminal-side communication unit 170, and the web browser execution unit 180 shown in FIG. A program that realizes the function of “part”). This program is loaded into the memory 903, read into the processor 901, and executed by the processor 901. Further, the auxiliary storage device 902 also stores an OS (Operating System). Then, at least a part of the OS is loaded into the memory 903, and the processor 901 executes a program that realizes the function of “unit” while executing the OS.
The terminal-side communication unit 170 of the decimator class positioning terminal device 100 includes hardware that transmits and receives signals and a communication control program that controls the hardware. The terminal-side communication unit 170 uses the communication control program to communicate an electronic map from the map distribution server 200B that distributes the electronic map generated using the original period coordinates to the map acquisition server 200A by communication with the map acquisition server 200A. Of these, the partial electronic map 531 including the current position 521 is acquired. The terminal-side communication unit 170 is a providing device 8200C that provides a crustal movement correction parameter 510, which is a conversion parameter 8510 used to convert the current position 521 to the original period coordinates, to the map acquisition server 200A by a communication control program. The crustal movement correction parameter 510 is acquired from the correction parameter generation server 200C. The terminal-side communication unit 170 causes the map acquisition server 200A to convert the current position 521 to the original coordinates using the crustal movement correction parameter 510 by the communication control program. The terminal-side communication unit 170 causes the map acquisition server 200 </ b> A to transmit the partial electronic map 531 and the conversion position 522 that is the current position 521 converted into the original period coordinates by the communication control program.

  Although one processor 901 is illustrated in FIG. 13, the decimator class positioning terminal device 100 may include a plurality of processors 901. A plurality of processors 901 may execute a program for realizing the function of “unit” in cooperation with each other. In addition, information, data, signal values, and variable values indicating the processing results of “unit” are stored in the memory 903, the auxiliary storage device 902, or a register or cache memory in the processor 901.

  “Parts” may be provided by “Processing Circuitry”. Further, “part” may be read as “circuit”, “process”, “procedure”, or “processing”. The “circuit” and the “processing circuit” are not only the processor 901 but also other types of processing circuits such as a logic IC, a GA (Gate Array), an ASIC (Application Specific Integrated Circuit), or an FPGA (Field-Programmable Gate Array). Is a concept that also includes

  10 electronic reference point, 20 centimeter class positioning reinforcement information generation device, 21 electronic reference point observation data collection unit, 22 centimeter class positioning reinforcement information generation unit, 23 centimeter class message generation unit, 30 main control station, 40 tracking control Station, 50 quasi-zenith satellite, 61,62 GPS satellite, 70 centimeter class positioning terminal, 81 public Wi-Fi network, 82 Internet, 100 decimator class positioning terminal apparatus, 101, 101-1 terminal side positioning unit, 103 terminal side Communication unit, 110 GNSS positioning signal antenna, 120 GNSS receiving unit, 130 positioning calculation unit, 140 Wi-Fi adapter, 150 decoder, 155 terminal side map acquisition unit, 160 battery, 170 terminal side communication unit, 180 web browser execution unit 190 display, 200 web server, 2 00A map acquisition server, 211A transmission unit, 212A reception unit, 220A map assembly unit, 230A crustal deformation correction unit, 240A storage unit, 200B map distribution server, 210B map distribution unit, 200C correction parameter generation server, 210C crustal deformation correction parameter generation Unit, 200D database device, 300, 300-1 Decimator-class positioning reinforcement information generating device, 310 storage unit, 311 centimeter-class positioning reinforcement information storage region, 312 navigation message storage region, 313 environment setting parameter storage region, 314 electronic reference point Data storage area, 315 Crustal deformation correction parameter storage area, 316 original coordinate storage area, 320 decimator class message generation unit, 330 decimator class reinforcement information evaluation unit, 340 supervision unit, 350 external I / F unit, 400 maintenance Personal computer, 510 Crustal deformation correction parameter, 521 Current position, 522 Conversion position, 523 Position related information, 524 User request, 531 Partial electronic map, 541 Positioning signal, 550 Original position coordinate, 551 Measurement position coordinate, 610 cm class Positioning reinforcement information, 620 Decimator class positioning reinforcement information, 1000 Position conversion system, 8100 Positioning terminal device, 8130 Terminal side conversion unit, 8140 Terminal side conversion parameter acquisition unit, 8180 Terminal side display processing unit, 8190 Terminal side display unit, 8200A Position Conversion device, 8211A conversion-side transmission unit, 8212A conversion-side reception unit, 8220A conversion-side map acquisition unit, 8230A conversion-side conversion unit, 8240A conversion-side storage unit, 8200B distribution device, 8200C providing device, 8510 conversion parameter 8610 first positioning reinforcement information, 8620 the second of positioning reinforcement information.

Claims (10)

A position conversion system comprising a positioning terminal device and a position conversion device,
The positioning terminal device
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal side communication unit for transmitting the current position;
A terminal side display,
A terminal-side display processing unit,
The position conversion device includes:
A conversion side receiving unit for receiving the current position;
When the current position is received, a conversion-side map acquisition unit that acquires a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
When the current position is received, the conversion parameter is obtained from a providing device that provides a conversion parameter used to convert the current position into the original period coordinates, and the current position is determined using the conversion parameter. A conversion side conversion unit for converting to the original period coordinates;
A conversion side transmission unit that transmits the partial electronic map and the conversion position that is the current position converted into the original period coordinates to the positioning terminal device;
The terminal side communication unit
Receiving the partial electronic map and the converted position;
The terminal-side display processing unit
The position conversion system which displays the said partial electronic map on the said terminal side display part, and displays the said conversion position on the said partial electronic map. The conversion parameter is:
Based on the measurement position coordinates of the electronic reference point measured after the original period of the electronic map and the original position coordinates of the electronic reference point in the electronic map, it is generated as information reflecting crustal movement. The position conversion system according to claim 1. The conversion parameter is:
The position conversion system according to claim 2, wherein the position conversion system is generated as a coefficient of a Chebyshev function that is a multi-dimensional two-dimensional collocation orthogonal polynomial. The conversion parameter is:
The position conversion system according to claim 2, wherein the position conversion system is generated as a component of a matrix that converts the measurement position coordinates of the electronic reference point to the original position coordinates of the electronic reference point. The terminal side communication unit
Along with the current location, send a user request to request acquisition of location related information related to the current location,
The conversion side receiver is
Receiving the user request with the current location;
The position conversion device further includes:
A search-side storage unit that searches for the position-related information that the user request requests acquisition and stores the search result, the user request, and the conversion position in a database device in association with each other.
The conversion side transmitter is
The position conversion system according to any one of claims 1 to 4, wherein a search result of the position related information is transmitted to the positioning terminal device. The terminal side positioning unit is
6. The current position is calculated using the positioning signal and the second positioning reinforcement information obtained by degrading the first positioning reinforcement information used for correcting the positioning error. The position conversion system according to claim 1. A positioning terminal device that measures the current position,
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal side communication unit that transmits the current position to a position conversion device that converts the current position;
A terminal side display,
A terminal-side display processing unit,
The terminal side communication unit
By communicating with the position conversion device,
Causing the position conversion device to acquire a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
Causing the position conversion device to acquire the conversion parameter from a providing device that provides a conversion parameter used to convert the current position to the original period coordinate;
The position conversion device, using the conversion parameter to convert the current position to the original coordinates,
The position conversion device, the partial electronic map and the conversion position that is the current position converted to the original period coordinates,
Receiving the partial electronic map and the conversion position transmitted to the position conversion device;
The terminal-side display processing unit
A positioning terminal device that displays the partial electronic map on the terminal-side display unit and displays the conversion position on the partial electronic map. On the computer,
The process of calculating the current position using the positioning signal transmitted from the satellite,
A process of transmitting the current position to a position conversion device that converts the current position;
By communicating with the position conversion device,
Processing for acquiring a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original coordinates to the position conversion device;
A process for causing the position conversion device to acquire the conversion parameter from a providing device that provides a conversion parameter used to convert the current position to the original period coordinate;
Processing for converting the current position to the original coordinate using the conversion parameter for the position conversion device,
Processing for transmitting the partial electronic map and the converted position which is the current position converted into the original period coordinates to the position converting device;
Processing for receiving the partial electronic map and the conversion position transmitted to the position conversion device;
A position conversion program for executing the process of displaying the partial electronic map and displaying the conversion position on the partial electronic map. A positioning terminal device that measures the current position,
A terminal side positioning unit that calculates the current position using the positioning signal transmitted from the satellite,
A terminal-side map acquisition unit that acquires a partial electronic map including the current position among the electronic map from a distribution device that distributes the electronic map generated using the original period coordinates;
A terminal-side conversion parameter acquisition unit that acquires the conversion parameter from a providing device that provides a conversion parameter used to convert the current position into the original period coordinate;
A terminal side conversion unit that converts the current position into the original period coordinates using the conversion parameter;
A terminal side display,
A positioning terminal device comprising: a terminal-side display processing unit that displays the partial electronic map on the terminal-side display unit, and displays the conversion position that is the current position converted into the original period coordinates on the partial electronic map. On the computer,
The process of calculating the current position using the positioning signal transmitted from the satellite,
Processing for obtaining a partial electronic map including the current position from the distribution device that distributes the electronic map generated using the original period coordinates;
Processing for obtaining the conversion parameter from a providing device that provides a conversion parameter used for converting the current position into the original period coordinate;
A process of converting the current position to the original coordinate using the conversion parameter;
Processing for displaying the partial electronic map and displaying the converted position which is the current position converted to the original period coordinates on the partial electronic map;
Position conversion program to execute.

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