JP6241045B2 - Communication system, in-vehicle device and distribution device - Google Patents

Description

  The present invention relates to a technique for performing positioning using a satellite positioning system.

  In a positioning method using a global positioning system (GNSS) such as GPS, positioning accuracy deteriorates due to various disturbances such as inaccuracy of positioning satellite position information and propagation delay (ionosphere / troposphere) due to the atmosphere.

  On the other hand, for example, in the Quasi-Zenith Satellite System (QZSS), which is a satellite positioning system developed in Japan, in addition to positioning signals compatible with GPS (GPS complementary signals) from satellites, positioning results based on positioning signals A reinforcement signal that can be used for correction is broadcast. In addition, as a satellite system for broadcasting the reinforcement signal, EU Galileo, China North Star, etc. are known. According to such a satellite positioning system, it is possible to improve the positioning accuracy by correcting the positioning result by receiving the reinforcement signal from the artificial satellite (see Patent Document 1).

JP 2012-73082 A

However, the positioning accuracy cannot be improved in a situation where the reinforcement signal cannot be received from the artificial satellite such as an environment where an obstacle exists in the zenith direction.
The present invention has been made in view of these problems, and an object of the present invention is to provide a technique for facilitating acquisition of a reinforcement signal used in a satellite positioning system.

The communication system of the present invention is configured such that the distribution device (1) and the in-vehicle device (2) can communicate with each other.
The distribution apparatus includes reinforcement signal acquisition means (S101) and distribution means (S401 to S409). The reinforcement signal acquisition unit acquires the reinforcement signal used in the satellite positioning system, and the distribution unit distributes the reinforcement signal to the in-vehicle device.

  On the other hand, the in-vehicle device includes positioning signal receiving means (S701), reinforcement signal receiving means (S601), and positioning means (S702 to S706). The positioning signal receiving means receives the positioning signal from the artificial satellite (4, 5), and the reinforcement signal receiving means receives the reinforcement signal from the distribution device. Then, the positioning means performs positioning using the positioning signal and the reinforcement signal.

  According to such a communication system, since the in-vehicle device can receive the reinforcement signal from the distribution device even when the reinforcement signal cannot be received from the satellite for the satellite positioning system, the reinforcement used in the satellite positioning system. Signals can be easily acquired.

  In addition, the code | symbol in the parenthesis described in this column and a claim shows the correspondence with the specific means as described in embodiment mentioned later as one aspect, Comprising: The technical scope of this invention is shown. It is not limited.

  In addition to the above-described communication system, the present invention also includes an in-vehicle device or a distribution device constituting the communication system, a program for causing a computer to function as the in-vehicle device or the distribution device, a recording medium in which the program is recorded, and a communication It can be realized in various forms such as a method.

It is a figure which shows the structure of the communication system of 1st Embodiment. It is a figure which shows the other example of a delivery server. It is a block diagram which shows the structure of a delivery server. It is a block diagram which shows the structure of onboard equipment. It is a data flow figure which shows the outline | summary of the process performed with a communication system. It is a flowchart of a reinforcement signal reception process. It is a flowchart of a request process. It is a flowchart of a request transmission process. It is a flowchart of a reinforcement signal delivery process. It is a flowchart which shows the detail of a process of S409 of 1st Embodiment. It is a flowchart of a reinforcement signal reception process. It is a flowchart of a positioning process. It is a figure which shows the structure of the communication system of 2nd Embodiment. It is a flowchart which shows the detail of the process of S409 of 2nd Embodiment. It is a figure which shows the structure of the communication system of 3rd Embodiment.

Embodiments to which the present invention is applied will be described below with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
The communication system shown in FIG. 1 includes a distribution server 1 and an in-vehicle device 2 mounted on a vehicle 2A. The distribution server 1 is implemented as, for example, a WEB (HTTP) server, and the distribution server 1 and the vehicle-mounted device 2 are configured to be capable of wireless communication via the Internet network 3A and the data communication base station 3B. The data communication base station 3B is, for example, a mobile data communication base station (3G, LTE, etc.) or a road-vehicle communication base station. In this embodiment, the mobile data communication base station is used. In addition, as shown in FIG. 2, the distribution server 1 (1B) that receives the reinforcement signal from another similar server, separately from the distribution server 1 (1A) that receives the reinforcement signal from the quasi-zenith satellite 4, as the distribution server 1. ) May be provided. Further, instead of the Internet network 3A, another digital network (Ethernet (registered trademark) LAN or wide area IP network) may be used.

As shown in FIG. 3, the distribution server 1 is roughly divided into a reinforcement signal receiving unit 11 and a reinforcement signal distribution unit 12.
The reinforcement signal receiving unit 11 is a component for realizing a function of receiving and storing the latest reinforcement signal broadcast from the artificial satellite (quasi-zenith satellite) 4 for the quasi-zenith satellite system. That is, the quasi-zenith satellite 4 broadcasts a positioning signal (GPS complementary signal) that is compatible with GPS and a reinforcement signal that can be used to correct the positioning result based on the positioning signal. The reinforcement signal represents information for each predetermined area (information common within the predetermined area), and has a longer lifetime (for example, several tens of seconds) than the positioning signal. That is, even if the reinforcement signal cannot be received directly from the quasi-zenith satellite 4, it can be used if it can be acquired by some route. Utilizing such a characteristic of the reinforcement signal, in the communication system of the present embodiment, the reinforcement signal broadcast from the quasi-zenith satellite 4 is distributed to the vehicle-mounted device 2 via the distribution server 1 as described below. The There are two types of reinforcement signals, L1-SAIF and LEX.

The reinforcement signal receiving unit 11 includes a reinforcement signal receiving antenna 111, a reinforcement signal receiver 112, a reinforcement signal updating unit 113, and a reinforcement signal database 114.
The reinforcement signal receiving antenna 111 is an antenna capable of receiving a reinforcement signal periodically broadcast from the quasi-zenith satellite 4, and is a fixed position on the ground (a place suitable for receiving the reinforcement signal from the quasi-zenith satellite 4). It is installed in a place different from the vehicle-mounted device 2.

  The reinforcement signal receiver 112 is a receiver for receiving the reinforcement signal via the reinforcement signal receiving antenna 111. After demodulating the reinforcement signal received from the quasi-zenith satellite 4 from an analog signal to a digital signal, the reinforcement signal is received. Transmit to the update unit 113.

  When the reinforcement signal update unit 113 receives a new reinforcement signal from the reinforcement signal receiver 112, the reinforcement signal update unit 113 updates the reinforcement signal stored in the reinforcement signal database 114. The reinforcement signal database 114 is a database for holding the latest reinforcement signal.

  On the other hand, the reinforcement signal distribution unit 12 transmits the latest reinforcement signal stored in the reinforcement signal reception unit 11 (reinforcement signal database 114) in response to the request for high accuracy transmitted from the vehicle-mounted device 2. It is a component for realizing the function of distributing to the device 2. The reinforcement signal distribution unit 12 includes a request reception unit 121, a user database 122, an authentication transmission control unit 123, and a reinforcement signal distribution unit 124.

  The request receiving unit 121 receives a high accuracy request from the vehicle-mounted device 2 via the Internet network 3A. A request for high accuracy is a request for distribution of a reinforcement signal, a one-time request for requesting one-time distribution of a reinforcement signal (one-time distribution), and a periodical request for periodic distribution of a reinforcement signal (multi-time distribution). It is roughly divided into a distribution request. In the periodic distribution request, a period for distributing the reinforcement signal (distribution period) and a time to end the distribution of the reinforcement signal (delivery time limit) are specified. Further, when receiving the request for high accuracy, the request receiving unit 121 returns an ACK signal. An ACK signal is a signal that is sent back from the receiving side to the transmitting side so that it can be confirmed on the transmitting side that the receiving side has received it correctly. Do.

  The user database 122 is a database for managing information related to users who are targets of the reinforcement signal distribution service, and is used when, for example, the targets of the reinforcement signal distribution service are limited in units of users or groups.

  The authentication transmission control unit 123 refers to the user database 122 to authenticate that the user who is the transmission source of the high accuracy request is the user who is the target of the reinforcement signal distribution service. In the user database 122, the status of each user (“waiting for request delivery”, “during regular delivery”, or “during service rejection”) is stored as information related to the user who is the target of the reinforcement signal delivery service.

  When the user status is “waiting for request distribution”, this means that the distribution of the reinforcement signal to the user is permitted. When the status of the user is “currently being distributed”, it means that the reinforcing signal is regularly distributed (during the distribution period) to the user. When the status of the user is “service refusal”, it means that the distribution of the reinforcement signal to the user is prohibited. The condition for prohibiting the distribution of the reinforcement signal can be set as appropriate, for example, unpaid for the reinforcement signal distribution service, and detailed description thereof is omitted in this embodiment.

  Then, the authentication transmission control unit 123 sends the transmission when the user who is the transmission source of the high-accuracy request is registered as a target of the reinforcement signal distribution service and the status is “waiting for request distribution”. Distribution destination information whose original is a distribution destination is distributed to the reinforcement signal distribution unit 124. In particular, when the high-accuracy request is a regular delivery request, the authentication transmission control unit 123 updates the status of the user to “regular delivery in progress” and registers the delivery cycle and the delivery deadline in the regular delivery task. , Start the scheduled delivery task. When the regular distribution task is activated, distribution destination information is distributed to the reinforcement signal distribution unit 124 for each distribution cycle. The regular delivery task ends when the delivery deadline arrives. When the regular delivery task ends, the authentication transmission control unit 123 updates the status of the user to “wait for request delivery”.

  Each time the reinforcement signal distribution unit 124 receives the distribution destination information from the authentication transmission control unit 123, the reinforcement signal distribution unit 124 transmits the reinforcement signal stored in the reinforcement signal database 114 via the Internet network 3A and the mobile data communication network. Deliver to the destination indicated by. Specifically, the reinforcement signal distribution unit 124 transmits the reinforcement signal as IP unicast when there is one distribution destination in the same base station, and transmits the reinforcement signal as IP unicast when there are a plurality of distribution destinations within the same base station. Delivered as multicast. Note that the reinforcement signal distribution unit 124 performs redistribution when an ACK signal is not received for a certain period of time after IP unicast.

On the other hand, as shown in FIG. 4, the vehicle-mounted device 2 is roughly divided into a data communication unit 21, a positioning unit 22, and a vehicle control unit 23.
The data communication unit 21 is a component for realizing a function of receiving a reinforcement signal from the distribution server 1 and includes a transmission / reception antenna 211 and a communication device 212.

The transmission / reception antenna 211 is connected to a communication device 212 corresponding to the communication method (mobile data communication method in this embodiment) of the data communication base station 3B.
The communication device 212 performs high-accuracy request transmission processing and reinforcement signal reception processing as communication processing with the distribution server 1 via the mobile data communication network (data communication base station 3B) and the Internet network 3A. Each time the communication device 212 receives a request command from the vehicle control unit 23, the communication device 212 transmits a high accuracy request to the distribution server 1. The request command is a command (reinforcement signal acquisition command) for transmitting a high accuracy request to the distribution server 1. However, the communication device 212 can also function in an operation mode in which a high accuracy request is automatically automatically transmitted to the distribution server 1 without waiting for a request command from the vehicle control unit 23. For example, automatic transmission may be started when the engine of the vehicle 2A is started, and automatic transmission may be stopped when the engine is stopped. The communication device 212 transmits the received reinforcement signal to the positioning calculation unit 223.

  The positioning unit 22 receives a positioning signal and a reinforcement signal broadcast from the quasi-zenith satellite 4 and a positioning signal broadcast from a GPS artificial satellite (GPS satellite) 5 to realize a function of obtaining a positioning result. It is a component part. The positioning unit 22 includes a positioning signal receiving antenna 221, a positioning signal receiving unit 222, and a positioning calculation unit 223.

The positioning signal receiving antenna 221 is an antenna capable of receiving a positioning signal and a reinforcement signal broadcast from the quasi-zenith satellite 4 and a positioning signal broadcast from the GPS satellite 5.
The positioning signal receiving unit 222 is a receiving unit for receiving the positioning signal and the reinforcement signal via the positioning signal receiving antenna 221, demodulates the received positioning signal and the reinforcement signal, and transmits the demodulated signal to the positioning calculation unit 223.

  In a situation where an effective reinforcement signal is not obtained, the positioning calculation unit 223 performs vehicle control on a positioning result based on the positioning signal (a positioning result that does not use the reinforcement signal, hereinafter referred to as “GPS single positioning result”). It transmits to the part 23. An effective reinforcement signal means a reinforcement signal whose lifetime has not expired (a reinforcement signal whose elapsed time from a reference time point (for example, when the reinforcement signal is transmitted) is equal to or less than a reference value). On the other hand, in a situation where an effective reinforcement signal is obtained, the positioning calculation unit 223 corrects the GPS single positioning result with the reinforcement signal, and the corrected high-precision positioning result (hereinafter referred to as “high-precision positioning result”). ) Is transmitted to the vehicle control unit 23. The correction here is performed according to a general L1-SAIF or LEX correction algorithm. In addition, the positioning calculation unit 223 transmits the positioning result to the communication device 212. The positioning result transmitted from the positioning calculation unit 223 includes, in addition to information obtained by normal GPS positioning (latitude / longitude / direction / speed / number of positioning satellites, etc.), either a high-precision positioning result or a GPS single positioning result. A flag that can determine whether or not there is included.

The vehicle control unit 23 is a component for realizing vehicle control, and includes a navigation system 231, a user interface 232, and a vehicle control ECU 233.
The navigation system 231 is a system for managing the traveling route of the own vehicle (the planned traveling route searched by the route search), and has a road map and a satellite quality prediction map. The road map includes information related to the width of the road and information related to the road where the zenith obstacle is present (for example, under a bridge, in a building, or an underground road). In addition, the satellite quality prediction map includes information on satellite quality corresponding to the location (for example, information on a location with poor satellite quality).

  The user interface 232 is a device that receives an input for prompting switching between the normal operation mode and the advanced operation mode from the driver. The advanced driving mode is an operation mode in which automatic driving and driving assistance (passing driving assistance, parking assistance, etc.) are enabled, and the normal driving mode is an operation mode in which these are disabled.

  The vehicle control ECU 233 is an electronic control device that performs vehicle control for automatic driving and driving support based on the positioning result received from the positioning unit 22. Automatic driving refers to a driving state in which the vehicle 2A itself performs acceleration / deceleration operations and steering operations. Driving support refers to a driving state in which driving is supported by voice or an assist operation while being based on manual driving by a driver.

  The vehicle control ECU 233 transmits a request command to the communication device 212 in a situation where a high-precision positioning result is required as a positioning result. Specifically, the vehicle control ECU 233 selects and transmits one of a request command that specifies a one-time request and a request command that specifies a periodic distribution request. For example, the periodic distribution request is specified when there is a high possibility that the required status of the high-precision positioning result will continue for a long period of time. Here, the situation where a high-precision positioning result is required is, for example, the following situations (1) to (3).

(1) Situations where detailed driving assistance is required, such as passing through narrow roads, passing each other, or parking.
(2) During transition from manual operation to automatic operation mode and during automatic operation mode.

  (3) Entering a location where the quality of the positioning result is poor or where the positioning result is interrupted (for example, under a bridge, underground, in a building, a place that is considered bad on the probed satellite quality prediction map), or A situation in which it is grasped based on a map that you are in such a place.

  In addition, when the highly accurate positioning result cannot be obtained, the vehicle control ECU 233 switches the content of the vehicle control to a service state that is one step lower. Here, the switching to the service state one step lower is, for example, the following (1) to (4).

(1) Switching from the automatic operation mode to the manual operation mode (notification to the driver).
(2) Switching from the available state to the additional usage state (notification to the driver) for driving assistance such as passing through a narrow road or passing another vehicle.

  (3) Regarding driving assistance for parking, switching from assistance based on positioning results to assistance based on sonar and cameras. This switching reduces the number of parking places that can be supported.

  (4) For roads that are subject to selection on the premise of automatic driving or driving assistance, narrow roads that require high-precision positioning are excluded from selection (only wide roads that do not require high-precision positioning are subject to selection. Switch to mode).

[1-2. Overview of processing]
Next, an outline of processing executed in the communication system of the present embodiment will be described with reference to FIG.

  The reinforcement signal periodically broadcast from the quasi-zenith satellite 4 is received by the distribution server 1 (S11). In the distribution server 1, the reinforcement signal modulated in analog is demodulated and converted into a digital signal message, and the reinforcement signal stored in the reinforcement signal database 114 is updated to the latest reinforcement signal.

  The positioning signal and the reinforcement signal broadcast from the quasi-zenith satellite 4 and the positioning signal broadcast from the GPS satellite 5 are received by the positioning unit 22 of the vehicle-mounted device 2. In a situation where an effective reinforcement signal is not obtained by the vehicle-mounted device 2, a GPS single positioning result based on the positioning signal is transmitted from the positioning unit 22 to the vehicle control unit 23 (S12). Vehicle control based on the positioning result is performed.

  On the other hand, in a situation where the vehicle control unit 23 requires a high-precision positioning result, a request command is transmitted from the vehicle control unit 23 to the data communication unit 21 (S13). When the request command is received by the data communication unit 21, a high accuracy request is transmitted from the data communication unit 21 to the data communication base station 3B according to the mobile data communication protocol (S14). Note that the communication packet (payload) of the high accuracy request includes information indicating the vehicle position.

  When the high accuracy request is received by the data communication base station 3B, an ACK signal is returned from the data communication base station 3B to the data communication unit 21 (S15), and the Internet communication is transmitted from the data communication base station 3B to the distribution server 1. A high precision request is transmitted according to the protocol (S16). When the high precision request is received by the distribution server 1, an ACK signal is returned from the distribution server 1 to the data communication base station 3B (S17). Further, the reinforcement signal is distributed from the distribution server 1 to the data communication base station 3B as a response to the high accuracy request (S18). The distribution destination of the reinforcement signal is set as the transmission source of the high accuracy request.

  When the reinforcement signal is received by the data communication base station 3B, an ACK signal is returned from the data communication base station 3B to the data communication unit 21 (S19), and the reinforcement signal is distributed from the data communication base station 3B to the data communication unit 21. (S20). When the reinforcement signal is received by the data communication unit 21, an ACK signal is returned from the data communication unit 21 to the data communication base station 3B (S21), and the reinforcement signal is transmitted from the data communication unit 21 to the positioning unit 22 (S22). ).

  In the positioning unit 22, the positioning result based on the positioning signal is corrected with the reinforcement signal, and the corrected high-precision positioning result is transmitted to the vehicle control unit 23 (S23). The vehicle control unit 23 performs vehicle control based on the high-precision positioning result.

  While the situation where the vehicle control unit 23 requires a high-precision positioning result continues, the request command is periodically sent from the vehicle control unit 23 to the data communication unit 21 (the lifetime of the received reinforcement signal is cut off). Before) (S24). Thereby, the same communication process is repeated. In the vehicle control unit 23, a valid reinforcement signal that has already been received is used until a new reinforcement signal is received. If no ACK signal is received for the transmitted information, the information is retransmitted (S25).

[1-3. Processing procedure]
Next, a specific processing procedure of processing executed in each of the distribution server 1 and the vehicle-mounted device 2 will be described.

First, reinforcement signal reception processing executed by the reinforcement signal update unit 113 of the distribution server 1 will be described with reference to the flowchart of FIG.
When the reinforcement signal reception process of FIG. 6 is started, the reinforcement signal update unit 113 waits for a reinforcement signal from the quasi-zenith satellite 4 (S101).

  When the reinforcement signal is received, the reinforcement signal update unit 113 compares the received reinforcement signal with the reinforcement signal stored in the reinforcement signal database 114, and determines whether or not the received reinforcement signal is newer. Is determined based on, for example, the time stamp of each reinforcement signal (S102).

  If the reinforcement signal update unit 113 determines that the received reinforcement signal is older (S102: NO), the process returns to S101. On the other hand, if it is determined that the received reinforcement signal is newer (S102: YES), the reinforcement signal update unit 113 replaces the reinforcement signal stored in the reinforcement signal database 114 with the received reinforcement signal. After (S103), the process returns to S101.

  Next, request processing executed by the vehicle control ECU 233 of the vehicle-mounted device 2 will be described with reference to the flowchart of FIG. The request processing is repeatedly executed at a predetermined cycle (an interval shorter than the lifetime of the reinforcement signal).

  When the request process of FIG. 7 is started, the vehicle control ECU 233 determines whether or not the advanced operation mode is set according to an instruction from the driver via the user interface 232 (S201). When it is determined that the advanced operation mode is set (S201: YES), the vehicle control ECU 233 transmits a request command to the communication device 212 (S202), and then returns the process to S201.

  On the other hand, when it is determined that the advanced operation mode is not set (S201: NO), the vehicle control ECU 233 acquires information on the road map, the satellite quality prediction map, and the travel route from the navigation system 231 (S203). Subsequently, the vehicle control ECU 233 determines whether or not a narrow road (for example, a road having a width equal to or less than a predetermined value) is included on the travel route based on the road map and the travel route (S204). If the vehicle control ECU 233 determines that a narrow road is included on the travel route (S204: YES), the vehicle control ECU 233 transmits a request command to the data communication unit 21 (S202), and then returns the process to S201.

  On the other hand, if the vehicle control ECU 233 determines that a narrow road is not included on the travel route (S204: NO), the road where the zenith obstacle exists on the travel route (for example, under the bridge, underground or building) Is determined based on the road map and the traveling route (S205). When the vehicle control ECU 233 determines that the road where the zenith obstacle is present is included on the traveling route (S205: YES), the vehicle control ECU 233 transmits a request command to the data communication unit 21 (S202), and then proceeds to S201. return.

  On the other hand, if the vehicle control ECU 233 determines that the road where the zenith obstacle is present is not included on the travel route (S205: NO), the vehicle control ECU 233 determines whether or not the travel route includes a place with a low satellite quality. The determination is made based on the satellite quality prediction map and the traveling route (S206). If the vehicle control ECU 233 determines that a place with poor satellite quality is included on the travel route (S206: YES), the vehicle control ECU 233 transmits a request command to the data communication unit 21 (S202), and then returns the process to S201.

  On the other hand, if the vehicle control ECU 233 determines that a place with poor satellite quality is not included on the travel route (S206: NO), the vehicle control ECU 233 returns the process to S201 as it is (without transmitting a request command).

Next, a request transmission process executed by the communication device 212 of the vehicle-mounted device 2 will be described with reference to the flowchart of FIG.
When the request transmission process of FIG. 8 is started, the communicator 212 waits for a request command from the vehicle control ECU 233 (S301). When the request command is received, the communication device 212 transmits a high accuracy request to the distribution server 1 (S302), and then returns the process to S301. Specifically, the communication device 212 transmits the specified request as a high-accuracy request depending on whether the request command specifies a one-time request or a periodic distribution request.

Next, reinforcement signal distribution processing executed by the reinforcement signal distribution unit 12 of the distribution server 1 will be described with reference to the flowchart of FIG.
When the reinforcement signal distribution processing of FIG. 9 is started, the reinforcement signal distribution unit 12 waits for a request for high accuracy from the vehicle-mounted device 2 (S401).

When the high accuracy request is received, the reinforcement signal distribution unit 12 refers to the information of the user who is the transmission source of the high accuracy request in the user database 122 (S402).
Subsequently, the reinforcement signal distribution unit 12 determines whether or not the user who is the transmission source of the high accuracy request is a user who is a target of the reinforcement signal distribution service (S403). If the reinforcement signal distribution unit 12 determines that the user is not the target of the reinforcement signal distribution service (S403: NO), the process returns to S401.

  On the other hand, if the reinforcement signal distribution unit 12 determines that the user is the target of the reinforcement signal distribution service (S403: YES), the reinforcement signal distribution unit 12 determines whether the high accuracy request is a regular distribution request (S404). ). When the reinforcement signal distribution unit 12 determines that the high-accuracy request is not a regular distribution request (a one-time request) (S404: NO), the process proceeds to S409.

  On the other hand, if the reinforcement signal distribution unit 12 determines that the high-accuracy request is a regular distribution request (S404: YES), both the distribution cycle and the distribution deadline specified in the high-accuracy request are appropriate. It is determined whether or not (S405). The determination as to whether or not it is appropriate is made based on, for example, a determination criterion as to whether or not the processing capability of the reinforcement signal distribution unit 12 or the network is expected to be overloaded.

  When it is determined that at least one of the distribution cycle and the distribution deadline is not appropriate (S405: NO), the reinforcement signal distribution unit 12 corrects the inappropriate value to a value within an appropriate range (S406), and then performs the process. The process proceeds to S407. The correction referred to here is a correction in a direction that suppresses an increase in the amount of communication associated with distribution, such as a modification that lengthens the distribution cycle or a modification that shortens the distribution deadline. On the other hand, if the reinforcement signal distribution unit 12 determines that both the distribution cycle and the distribution time limit are appropriate (S405: YES), the reinforcement signal distribution unit 12 proceeds to S407 as it is.

  Subsequently, the reinforcement signal distribution unit 12 registers the distribution cycle and the distribution deadline in the regular distribution task (S407), activates the regular distribution task (S408), and shifts the processing to S409. When the regular distribution task is activated, the process of S409 is executed for each distribution cycle until the distribution deadline comes after the current process.

Subsequently, the reinforcement signal distribution unit 12 reads the reinforcement signal from the reinforcement signal database 114, distributes the transmission source as the distribution destination (S409), and then returns the process to S401.
Specifically, the process of S409 is executed as shown in FIG. That is, the reinforcement signal distribution unit 12 first refers to the distribution destination information (S501). Subsequently, the reinforcement signal distribution unit 12 determines whether another user (on-vehicle device 2) that transmits the request for high accuracy exists in the same multicast group (in the same base station in the present embodiment) (S502). ). When it is determined that no other user exists in the same multicast group (S502: NO), the reinforcement signal distribution unit 12 distributes the reinforcement signal as IP unicast (S503). That is, the reinforcement signal is distributed using one vehicle-mounted device 2 as a distribution destination. On the other hand, if it is determined that another user exists in the same multicast group (S502: YES), the reinforcement signal distribution unit 12 distributes the reinforcement signal as an IP multicast (S504). That is, the reinforcement signal is distributed using a plurality of vehicle-mounted devices 2 as distribution destinations.

Next, the reinforcement signal reception process which the communication apparatus 212 of the onboard equipment 2 performs is demonstrated using the flowchart of FIG.
When the reinforcement signal reception process of FIG. 11 is started, the communication device 212 waits for a reinforcement signal from the distribution server 1 (S601). When the reinforcement signal is received, the communication device 212 sends the received reinforcement signal to the positioning calculation unit 223 (S602), and returns the process to S601.

Next, the positioning process which the positioning calculating part 223 of the onboard equipment 2 performs is demonstrated using the flowchart of FIG.
When the positioning process of FIG. 12 is started, the positioning calculation unit 223 waits for a positioning signal broadcast from the GPS satellite 5 (S701).

  When the positioning signal is received, the positioning calculation unit 223 determines whether or not a valid reinforcement signal is obtained (S702). If the positioning calculation unit 223 determines that a valid reinforcement signal is obtained (S702: YES), the positioning calculation unit 223 performs a positioning calculation using the reinforcement signal to obtain a high-precision positioning result (S703). Subsequently, the positioning calculation unit 223 transmits the high-precision positioning result to the vehicle control ECU 233 (S704), and then returns the process to S701.

  On the other hand, if the positioning calculation unit 223 determines that the effective reinforcement signal is not obtained (S702: NO), the positioning calculation unit 223 performs the positioning calculation without using the reinforcement signal to obtain the GPS single positioning result (S705). ). Subsequently, the positioning calculation unit 223 transmits the GPS single positioning result to the vehicle control unit 23 (S706), and then returns the process to S701.

[1-4. effect]
According to the embodiment described above in detail, the following effects can be obtained.
[1A] In the communication system of the first embodiment, the distribution server 1 and the vehicle-mounted device 2 are configured to be communicable. And the delivery server 1 acquires the reinforcement signal used with a quasi-zenith satellite system (S101), and distributes the acquired reinforcement signal to the onboard equipment 2 (S401-S409). On the other hand, the vehicle-mounted device 2 not only receives the positioning signal and the reinforcement signal from the quasi-zenith satellite 4 and the GPS satellite 5 (S701), but also receives the reinforcement signal from the distribution server 1 (S601). Then, positioning is performed using the positioning signal and the reinforcement signal (S702 to S706). Therefore, according to the communication system of the first embodiment, since the vehicle-mounted device 2 can receive the reinforcement signal from the distribution server 1 even when the reinforcement signal cannot be received from the quasi-zenith satellite 4, the quasi-zenith satellite system. It is possible to easily obtain the reinforcement signal used in the above. Further, according to the communication system of the first embodiment, the reinforcement signal can be used even in the vehicle-mounted device 2 that does not have a configuration for receiving the reinforcement signal (for example, a dedicated antenna or a high-frequency demodulation unit). . In addition, in the configuration in which the reinforcement signal is received from the quasi-zenith satellite 4, for example, in a traveling environment in which an obstacle exists in the zenith direction, the reinforcement signal cannot be received, and vehicles such as automatic driving and driving assistance can be received. It may be necessary to temporarily lower or stop the control level of the control. On the other hand, according to the communication system of the first embodiment, highly reliable vehicle control can be realized even in a traveling environment where an obstacle exists in the zenith direction.

  [1B] In the communication system of the first embodiment, the distribution server 1 acquires a reinforcement signal from the quasi-zenith satellite 4. Therefore, according to the communication system of the first embodiment, the distribution server 1 can easily obtain the latest reinforcement signal.

  [1C] In the communication system of the first embodiment, the vehicle-mounted device 2 has a GPS single positioning result based on the positioning signal (first positioning result) in a situation where an effective reinforcement signal is not obtained (S702: NO). Is obtained (S705). On the other hand, in the situation where an effective reinforcement signal is obtained (S702: YES), the vehicle-mounted device 2 is a positioning result based on the positioning signal and the reinforcement signal, and is highly accurate with higher accuracy than the GPS single positioning result. A positioning result (second positioning result) is obtained (S703). Therefore, according to the communication system of the first embodiment, the vehicle-mounted device 2 can obtain an appropriate positioning result according to the presence or absence of an effective reinforcement signal.

  [1D] In the communication system of the first embodiment, the vehicle-mounted device 2 uses a reinforcement signal whose lifetime has not expired as an effective reinforcement signal (S702). Therefore, according to the communication system of the first embodiment, the vehicle-mounted device 2 suppresses that a low-reliability reinforcement signal is used for positioning and that a high-reliability reinforcement signal is not used for positioning. be able to.

  [1E] In the communication system according to the first embodiment, the vehicle-mounted device 2 requests the distribution server 1 to distribute a reinforcement signal (S302), and the distribution server 1 reinforces when receiving a request from the vehicle-mounted device 2. The signal is distributed to the vehicle-mounted device 2 (S401 to S409). Therefore, according to the communication system of 1st Embodiment, compared with the structure in which the delivery server 1 always delivers a reinforcement signal irrespective of the request | requirement from the onboard equipment 2, communication volume required in order to deliver a reinforcement signal is reduced. It becomes possible to reduce.

  [1F] In the communication system of the first embodiment, the vehicle-mounted device 2 does not request distribution of the reinforcement signal in a state (first state) that does not require a high-precision positioning result (S206: NO). On the other hand, the vehicle-mounted device 2 (S201: YES, S204: YES, S205) in a state that requires a high-precision positioning result (second state in which high-accuracy positioning is required compared to the first state). : YES, S206; YES), the distribution of the reinforcement signal is requested (S202). Therefore, according to the communication system of the first embodiment, the vehicle-mounted device 2 acquires the reinforcement signal from the distribution server 1 as necessary, so that in a situation where the positioning accuracy should be improved, the reinforcement is performed while performing high-precision positioning. The amount of communication required for signal distribution can be reduced.

  [1G] In the communication system according to the first embodiment, the vehicle-mounted device 2 periodically requests the distribution of the reinforcement signal in a state where a high-precision positioning result is required. Therefore, according to the communication system of the first embodiment, highly accurate positioning can be continuously performed in a state where a highly accurate positioning result is required.

  [1H] In the communication system according to the first embodiment, the vehicle-mounted device 2 requests the distribution of the reinforcement signal periodically in a state where a high-precision positioning result is required. Therefore, according to the communication system of the first embodiment, high-precision positioning can be continuously performed in a state where high-precision positioning results are required, and it is necessary for requesting distribution of the reinforcement signal. The amount of communication can be reduced.

  [1I] In the communication system of the first embodiment, the vehicle-mounted device 2 requests periodic distribution of the reinforcement signal by specifying a distribution deadline (distribution end condition). Therefore, according to the communication system of the first embodiment, it is not necessary to request the end of distribution at the time when the distribution of the reinforcement signal should be terminated.

  [1J] In the communication system of the first embodiment, the vehicle-mounted device 2 requests the distribution server 1 to distribute the reinforcement signal via the mobile data communication network. Therefore, according to the communication system of the first embodiment, the reinforcement signal can be received using the existing communication device.

  [1K] In the communication system according to the first embodiment, the distribution server 1 distributes the reinforcement signal to the vehicle-mounted device 2 via the mobile data communication network. Then, the distribution server 1 switches between distribution by unicast and distribution by multicast according to the number of vehicle-mounted devices 2 to which the reinforcement signal is distributed, belonging to the same multicast group (S502 to S504). Specifically, when there are a plurality of vehicle-mounted devices 2 to which the reinforcement signal is distributed within the same base station (S502: YES), the distribution is performed by multicast instead of unicast (S504). Therefore, according to the communication system of the first embodiment, the reinforcement signal can be efficiently distributed to the plurality of vehicle-mounted devices 2, and the radio wave band of mobile data communication can be reduced. In addition, since mobile data communication has a large transmission power and can use retransmission control, communication reliability can be improved compared to satellite broadcasting.

  In the first embodiment, the distribution server 1 corresponds to an example of a distribution device, the in-vehicle device 2 corresponds to an example of an on-vehicle device, and the quasi-zenith satellite 4 and the GPS satellite 5 correspond to an example of an artificial satellite. S101 corresponds to an example of processing as a reinforcement signal acquisition unit, S301 to S302 correspond to an example of processing as a reinforcement signal request unit, and S401 to S409 correspond to an example of processing as a distribution unit. Further, S601 corresponds to an example of processing as a reinforcement signal receiving unit, S701 corresponds to an example of processing as a positioning signal receiving unit, and S702 to S706 correspond to an example of processing as a positioning unit.

[2. Second Embodiment]
[2-1. Difference from the first embodiment]
Since the basic configuration of the communication system according to the second embodiment shown in FIG. 13 is the same as that of the communication system according to the first embodiment, description of the common configuration will be omitted, and differences will be mainly described.

  In the communication system (FIG. 1) of the first embodiment described above, the reinforcement signal from the distribution server 1 is distributed to the vehicle-mounted device 2 via the mobile data communication network (mobile data communication base station 3B). On the other hand, in the communication system of the second embodiment, reinforcement from the distribution server 1 is performed using a road-vehicle communication system that distributes information from the road-vehicle communication base station 3D installed on the road to the vehicle 2A on the road. The difference from the first embodiment is that the signal is distributed to the vehicle-mounted device 2. That is, the vehicle-mounted device 2 transmits a high accuracy request to the distribution server 1 through the mobile data communication base station 3B and the Internet network 3A, as in the first embodiment. On the other hand, when the distribution server 1 receives the high accuracy request, it distributes the reinforcement signal to the vehicle-mounted device 2 that is the transmission source of the high accuracy request via the road-to-vehicle communication network 3C and the road-to-vehicle communication base station 3D. . The road-vehicle communication network 3C is a network that connects the road-vehicle communication base stations 3D to each other via an Internet gateway. The vehicle-mounted device 2 receives the reinforcement signal from the distribution server 1 from the road-vehicle communication base station 3D.

[2-2. effect]
According to such a communication system of the second embodiment, the following effects are obtained in addition to the effects [1A] to [1J] of the first embodiment described above.

  [2A] In the communication system of the second embodiment, the distribution server 1 uses the road-to-vehicle communication system for distributing information from the road-to-vehicle communication base station 3D installed on the road to the vehicle 2A on the road. Is delivered to the vehicle-mounted device 2. Therefore, according to the communication system of the second embodiment, it is not necessary to use the mobile data communication network to distribute the reinforcement signal, and the communication amount of mobile data communication can be reduced. As a result, for example, it is possible to make a configuration in which transmission of a high-accuracy request from the vehicle-mounted device 2 is unnecessary, and a reinforcement signal is always distributed (broadcast) from the distribution server 1 to all the vehicle-mounted devices 2.

[2-3. Modified example]
In the communication system according to the second embodiment, the distribution server 1 may select a communication path for distributing the reinforcement signal to the vehicle-mounted device 2. Specifically, the reinforcement signal distribution unit 12 executes the process shown in FIG. 14 instead of the process shown in FIG. 10 described above. The processes in S801 and S804 to S806 in FIG. 14 are the same as the processes in S501 to S504 in FIG.

  As illustrated in FIG. 14, the reinforcement signal distribution unit 12 determines whether or not the distribution destination network is road-to-vehicle communication (S802). The delivery destination network is set to be the same as the communication path of the high accuracy request, for example. That is, when the high accuracy request from the vehicle-mounted device 2 is transmitted by mobile data communication, it is determined that the network of the delivery destination is mobile data communication, and when the request is transmitted by road-to-vehicle communication, It is determined that the delivery destination network is road-to-vehicle communication.

  When it is determined that the distribution destination network is road-to-vehicle communication (S802: YES), the reinforcement signal distribution unit 12 distributes the reinforcement signal as multicast by road-to-vehicle communication (S803). On the other hand, if the reinforcement signal distribution unit 12 determines that the distribution destination network is not road-to-vehicle communication (mobile data communication), the reinforcement signal distribution unit 12 performs processing for distributing the reinforcement signal through mobile data communication (S804 to S806). ). According to such a configuration, the distribution route of the reinforcement signal can be properly used according to the communication method or position of the vehicle-mounted device 2.

[3. Third Embodiment]
[3-1. Difference from the first embodiment]
The basic configuration of the communication system according to the third embodiment shown in FIG. 15 is the same as that of the communication system according to the first embodiment. Therefore, description of common configurations will be omitted, and differences will be mainly described.

  In the communication system (FIG. 1) of the first embodiment described above, the reinforcement signal managed by the distribution server 1 is acquired from the quasi-zenith satellite 4. On the other hand, the communication system of the third embodiment differs from the first embodiment in that the reinforcement signal managed by the distribution server 1 is acquired from the ground facilities. That is, there are ground monitor stations 3E as fixed stations for continuously observing GPS signals, and the observation results obtained at the ground monitor stations 3E in various places are generated via the monitor station network 3F. Collected by node 3G. The reinforcement signal generation node 3G generates a digital reinforcement signal according to the generation algorithm for the quasi-zenith satellite from the observation result acquired from the ground monitor station 3E in each place. The distribution server 1 acquires the reinforcement signal generated by the reinforcement signal generation node 3G.

[3-2. effect]
According to the communication system of the third embodiment, in addition to the effects [1A] and [1C] to [1K] of the first embodiment described above, the following effects can be obtained.

  [3A] In the communication system of the third embodiment, since the distribution server 1 acquires the reinforcement signal from the ground monitor station 3E, it cannot acquire the reinforcement signal as compared with the configuration in which the reinforcement signal is acquired from the quasi-zenith satellite 4. The situation can be made difficult to occur.

[4. Other Embodiments]
As mentioned above, although embodiment of this invention was described, it cannot be overemphasized that this invention can take a various form, without being limited to the said embodiment.

  [4A] In the above embodiment, the vehicle-mounted device 2 that can receive the reinforcement signal from the quasi-zenith satellite 4 is illustrated, but the present invention is not limited to this, and a configuration for receiving the reinforcement signal from the quasi-zenith satellite 4 is provided. The onboard equipment 2 which does not have may be sufficient.

  [4B] When the distribution server 1 manages reinforcement signals for a plurality of areas, the distribution server 1 may select and distribute the reinforcement signals according to the position of the vehicle-mounted device 2. In this way, it is possible to reduce the distribution of unnecessary reinforcement signals.

  [4C] In the above embodiment, the quasi-zenith satellite system is exemplified as the satellite system in which the reinforcement signal is broadcast. However, the present invention is not limited to this, and the present invention is not limited to this. For example, the present invention may be applied to EU Galileo or Chinese North Star.

  [4D] Each component of the present invention is conceptual and is not limited to the above embodiment. For example, the functions of one component may be distributed to a plurality of components, or the functions of a plurality of components may be integrated into one component. Further, at least a part of the configuration of the above embodiment may be replaced with a known configuration having the same function. In addition, at least a part of the configuration of the above embodiment may be added to or replaced with the configuration of the other embodiment.

  DESCRIPTION OF SYMBOLS 1 ... Distribution server, 2 ... Onboard equipment, 4 ... Quasi-zenith satellite, 5 ... GPS satellite, 11 ... Reinforcement signal receiving part, 12 ... Reinforcement signal distribution part, 21 ... Data communication part, 22 ... Positioning part, 23 ... Vehicle control 111: Reinforcing signal receiving antenna, 112 ... Reinforcing signal receiver, 113 ... Reinforcing signal updating unit, 114 ... Reinforcing signal database, 121 ... Request receiving unit, 124 ... Reinforcing signal distribution unit, 211 ... Transmission / reception antenna, 212 ... Communication 221 ... positioning signal receiving antenna, 222 ... positioning signal receiving unit, 223 ... positioning calculation unit, 233 ... vehicle control ECU

Claims (14)

A communication system configured to enable communication between the distribution device (1) and the in-vehicle device (2),
The distribution device includes:
Reinforcement signal acquisition means (S101) for acquiring the reinforcement signal used in the satellite positioning system from the first artificial satellite (4);
Distribution means (S401 to S409) for distributing the reinforcement signal to the in-vehicle device,
The in-vehicle device is
Mounted on the vehicle,
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
First reinforcement signal receiving means for receiving the reinforcement signal from the first artificial satellite;
Second reinforcement signal receiving means (S601) for receiving the reinforcement signal from the distribution device;
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The distribution means distributes the reinforcement signal to the in-vehicle device when receiving the request from the in-vehicle device,
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-accuracy positioning result is required, a periodic distribution of the reinforcement signal is requested by specifying a distribution end condition ,
The second state includes a state in which a road having a width equal to or less than a predetermined value is included on a traveling route of the vehicle . A communication system configured to enable communication between the distribution device (1) and the in-vehicle device (2),
The distribution device includes:
Reinforcement signal acquisition means (S101) for acquiring the reinforcement signal used in the satellite positioning system from the first artificial satellite (4);
Distribution means (S401 to S409) for distributing the reinforcement signal to the in-vehicle device,
The in-vehicle device is
Mounted on the vehicle,
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
First reinforcement signal receiving means for receiving the reinforcement signal from the first artificial satellite;
Second reinforcement signal receiving means (S601) for receiving the reinforcement signal from the distribution device;
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The distribution means distributes the reinforcement signal to the in-vehicle device when receiving the request from the in-vehicle device,
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-accuracy positioning result is required, a periodic distribution of the reinforcement signal is requested by specifying a distribution end condition ,
The communication system characterized in that the second state includes a state in which a road on which a predetermined zenith obstacle is present is included on the traveling route of the vehicle . A communication system configured to enable communication between the distribution device (1) and the in-vehicle device (2),
The distribution device includes:
Reinforcement signal acquisition means (S101) for acquiring the reinforcement signal used in the satellite positioning system from the first artificial satellite (4);
Distribution means (S401 to S409) for distributing the reinforcement signal to the in-vehicle device,
The in-vehicle device is
Mounted on the vehicle,
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
First reinforcement signal receiving means for receiving the reinforcement signal from the first artificial satellite;
Second reinforcement signal receiving means (S601) for receiving the reinforcement signal from the distribution device;
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The distribution means distributes the reinforcement signal to the in-vehicle device when receiving the request from the in-vehicle device,
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-accuracy positioning result is required, a periodic distribution of the reinforcement signal is requested by specifying a distribution end condition ,
The second state includes a state in which a predetermined place having a low satellite quality is included on a traveling route of the vehicle . The communication system according to any one of claims 1 to 3 , wherein
The said reinforcement signal acquisition means acquires the said reinforcement signal from the artificial satellite (4) for satellite positioning systems. The communication system characterized by the above-mentioned. The communication system according to any one of claims 1 to 3 , wherein
The said reinforcement signal acquisition means acquires the said reinforcement signal from a ground installation. The communication system characterized by the above-mentioned. A communication system according to any one of claims 1 to 5 , wherein
The positioning means obtains the first positioning result based on the positioning signal in a situation where the effective reinforcement signal is not obtained, while the positioning signal is obtained in a situation where the effective reinforcement signal is obtained. And a second positioning result that is a positioning result based on the reinforcing signal and is more accurate than the first positioning result. The communication system according to claim 6 ,
The positioning means uses the reinforcement signal whose lifetime has not expired as the effective reinforcement signal. The communication system according to any one of claims 1 to 7 ,
The reinforcing signal requesting means periodically requests distribution of the reinforcing signal in the second state. A communication system according to any one of claims 1 to 8 , wherein
The communication system according to claim 1, wherein the reinforcement signal requesting unit requests the distribution apparatus to distribute the reinforcement signal via a mobile data communication network. The communication system according to claim 9 , wherein
The distribution means distributes the reinforcement signal to the in-vehicle device via a mobile data communication network, and belongs to the same multicast group, depending on the number of the in-vehicle device to be distributed of the reinforcement signal, A communication system characterized by switching between unicast distribution and multicast distribution. A communication system according to any one of claims 1 to 10 , wherein
The distribution means distributes the reinforcement signal to the in-vehicle device using a road-vehicle communication system that distributes information from a road-vehicle communication base station to a vehicle. An in- vehicle device (2) mounted on a vehicle,
First reinforcement signal receiving means for receiving a reinforcement signal from the first artificial satellite (4);
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
The second reinforcement signal that receives the reinforcement signal from the distribution device (1) that obtains the reinforcement signal used in the satellite positioning system from the first artificial satellite and distributes it when a request is received from the in-vehicle device. Receiving means (S601);
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-precision positioning result is required,
Requesting periodic delivery of the reinforcement signal by specifying a delivery termination condition ;
The in-vehicle device, wherein the second state includes a state in which a road whose width is equal to or less than a predetermined value is included on a traveling route of the vehicle. An in- vehicle device (2) mounted on a vehicle,
First reinforcement signal receiving means for receiving a reinforcement signal from the first artificial satellite (4);
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
The second reinforcement signal that receives the reinforcement signal from the distribution device (1) that obtains the reinforcement signal used in the satellite positioning system from the first artificial satellite and distributes it when a request is received from the in-vehicle device. Receiving means (S601);
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-precision positioning result is required,
Requesting periodic delivery of the reinforcement signal by specifying a delivery termination condition ;
The in-vehicle device, wherein the second state includes a state where a road on which a predetermined zenith obstacle is present is included on the traveling route of the vehicle. An in- vehicle device (2) mounted on a vehicle,
First reinforcement signal receiving means for receiving a reinforcement signal from the first artificial satellite (4);
Positioning signal receiving means (S701) for receiving a positioning signal from the second artificial satellite (5);
The second reinforcement signal that receives the reinforcement signal from the distribution device (1) that obtains the reinforcement signal used in the satellite positioning system from the first artificial satellite and distributes it when a request is received from the in-vehicle device. Receiving means (S601);
Positioning means (S702 to S706) for positioning using the positioning signal and the reinforcement signal;
Reinforcing signal requesting means (S301 to S302) for requesting the distribution device to distribute the reinforcing signal;
The reinforcement signal requesting means requests distribution of the reinforcement signal in a first state where a high-precision positioning result that is a result of correcting a positioning result based on the positioning signal with the reinforcement signal is not required. First, in the second state where the high-precision positioning result is required,
Requesting periodic delivery of the reinforcement signal by specifying a delivery termination condition ;
The in-vehicle device, wherein the second state includes a state in which a predetermined place with a low satellite quality is included on the traveling route of the vehicle.

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