JP2006349405A - System for vehicle-vehicle communication - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for vehicle-vehicle communication which precisely measure the position of a car, even when D-GPS service cannot be used or even with a navigation system that is not loaded with position correction function by D-GPS method, and can precisely catch the mutual positions of vehicles present in the vicinity with a vehicle-vehicle communication. <P>SOLUTION: The system comprises a position identifying means for identifying the present position from signals, by receiving the signals transmitted from a plurality of satellites, a receiver means for receiving the position information from beacon transmitting signals, including the information on the position placed on a road, an error information operation means for acquiring error information indicating a shift between the position information and the present position, by comparing the position information received with the receiving means and the present position identified by the position identifying means, and a transmission means for transmitting the error information calculated by the error information calculation means. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vehicle-to-vehicle communication system, and more particularly to a vehicle-to-vehicle communication system suitable for correcting a positioning error of a navigation device using GPS.

  Conventionally, navigation systems using GPS (Global Positioning System) have been widely used. In this navigation system, radio waves of three or more satellites are simultaneously received by a receiver from a plurality of GPS satellites orbiting a predetermined satellite orbit, and a pseudo distance between the GPS satellite and the receiver is obtained. The true position of the receiver (such as a vehicle equipped with a navigation system) is obtained by correcting the distance. However, GPS is a system that was originally built for military purposes, and in the case of GPS standard positioning service (SPS) with some of its functions open to the private sector, it is only about 38m to 10m from the true position. There is no denying that an error occurs. For this reason, in order to improve the position detection accuracy, position correction information consisting of a difference between the position information obtained from the GPS satellites received at a known location and the true position information is obtained, and the position correction information is transmitted to the FM broadcast. On the other hand, the receiver (navigation system) side receives the position complementation information superimposed on the FM broadcast radio wave and corrects the GPS measurement error on the receiver (navigation system) side. It has been known. According to this D-GPS system, it is possible to make positioning error within about 5 m.

  Or, when you go to a campsite etc. with a recreational vehicle, the in-vehicle navigation device (car navigation device) is the main unit and a portable GPS receiver (slave unit) is owned by each family member in the vicinity of the recreational vehicle There is known a GPS support device that can improve the positioning accuracy of the slave unit when moving the mobile phone (see, for example, Patent Document 1). In this support apparatus, the master unit receives a radio wave from a GPS satellite and specifies its own position, and generates an error from a known current location (reference position) as error information. On the other hand, the slave unit receives a signal from a GPS satellite and measures the current position, requests the master unit to transmit error information, receives error information, and performs positioning based on the error information. The position of is corrected.

  In a navigation system using GPS, for example, while traveling on a road or the like sandwiched between tunnels or high-rise buildings, the navigation system may not be able to receive signals from GPS satellites (radio dead zone). There is also known a position correction device that estimates the current vehicle position from the position of the host vehicle, the speed of the host vehicle, and the moving direction measured immediately before reaching the radio dead zone when the vehicle reaches the radio dead zone (for example, , See Patent Document 2).

On the other hand, as a system using this type of GPS, there is a system that prevents collision accidents by exchanging vehicle position information with one function of advanced safety vehicle (ASV) of ITS (Advanced Road Traffic System). . This system, for example, detects a stopped vehicle that is difficult to detect from sensors mounted on the vehicle at places with poor visibility such as intersections and curves, and prevents a collision accident. This collision accident prevention system performs vehicle-to-vehicle communication via a communication device mounted on a vehicle and supports safe driving by mutually transmitting vehicle conditions (vehicle position, speed, moving direction, etc.). . In such a system, vehicle status is exchanged using inter-vehicle communication based on vehicle position information obtained from a navigation system.
JP 2002-31676 A JP 2002-350157 A

However, in the case of the navigation system adopting the D-GPS method described above, the position correction information is not transmitted outside the FM broadcast service area or in the broadcast stop time period, so the position information cannot be corrected and a positioning error occurs. There is a problem of growing.
In addition, if the master unit described in Patent Document 1 is arranged at a known location near the road and constructed as a navigation device in which the slave unit is mounted on a vehicle, positioning with higher accuracy can be performed. For this reason, there is a problem that it is necessary to prepare an infrastructure for this purpose, and enormous costs are required.

  By the way, in ITS (Intelligent Transport System) etc., it is desired to measure the vehicle position with high accuracy by exchanging the vehicle status between the vehicles by the inter-vehicle communication using the positioning information obtained by GPS and grasping the position of each other. It is rare. For this reason, although it is conceivable to apply the position correction apparatus described in Patent Document 2 to the navigation system, the position correction apparatus described in this document only calculates the delay time required for positioning of the GPS satellite from the change in the actual vehicle speed. There is a problem that it is estimated that it has moved by the positioning time, and has not reached a level applicable to a collision accident prevention system such as ASV.

  The present invention has been made in order to solve the above-described problems, and the object of the present invention is when the D-GPS service cannot be used outside the FM broadcast service area or during broadcast stop time, or the position based on the D-GPS system. A vehicle-to-vehicle communication system that can accurately measure the position of a vehicle even in a navigation system that is not equipped with a correction function, and that can complement each other's vehicle position in the vicinity with vehicle-to-vehicle communication. It is to provide.

  In order to achieve the above-described object, the inter-vehicle communication system of the present invention is provided on the road with position specifying means for receiving signals transmitted from a plurality of satellites and specifying the current position based on these signals. The receiving means for receiving the position information from the beacon that transmits a signal including the installed position information, and the position information received by the receiving means and the current position specified by the position specifying means are compared. Error information calculating means for obtaining error information indicating a deviation between the position information and the current position, and transmitting means for transmitting the error information calculated by the error information calculating means.

  Specifically, the above-described beacon is an optical beacon sent from a light projecting / receiving unit 50 installed on a road as a VICS (vehicle information and communication system) as shown in FIG. In addition to information on the location where the light projecting / receiving unit 50 is arranged (position information) for a vehicle passing through a predetermined range directly below the light receiving unit 50 (for example, a range of about 3.5 m with respect to the traveling direction), traffic congestion Various types of information such as information and road fault information are sent out. Incidentally, the light projecting / receiving unit 50 that sends out a VICS beacon (optical beacon) is installed mainly in the vicinity of an intersection and provides the above-described various information and the like for 24 hours.

  The vehicle-to-vehicle communication system described above specifies the current position based on signals transmitted from a plurality of GPS satellites, while the beacon is provided on the road and transmits a signal including the installed position information. And the current position measured by signals transmitted from a plurality of GPS satellites is compared with the position information transmitted from the beacon to obtain a measurement error measured by the GPS satellites. Then, error information that can correct the deviation of the current position specified by the GPS satellites is transmitted to neighboring vehicles.

Preferably, the transmission means further transmits satellite identification information indicating a plurality of the satellites used for specifying the current position.
The vehicle-to-vehicle communication system described above prevents erroneous error correction due to the difference in received GPS satellites.
The vehicle-to-vehicle communication system of the present invention is characterized by comprising position correction means for receiving the error information transmitted by the transmission means and correcting the current position specified by the position specifying means.

  As a result, the inter-vehicle communication system described above receives this error information from a nearby vehicle that has obtained error information for correcting the measurement error of the current position measured by the GPS satellite, and corrects the current vehicle position with high accuracy.

  Thus, according to the vehicle-to-vehicle communication system according to claim 1 of the present invention, a signal from a beacon that transmits known position information is received, and a deviation from a current position specified by a signal from a GPS satellite is received. Since (error) is obtained and this error information is transmitted to neighboring vehicles, the neighboring vehicles that have received this correction information can correct the position of the navigation system mounted on each vehicle. This position correction is performed every time a nearby vehicle receives a signal from the beacon, so even if there is a change in the propagation state of the signal transmitted from the satellite or the position of the satellite, the latest GPS Position correction information (error information) can be transmitted.

  According to the inter-vehicle communication system according to claim 2 of the present invention, the error information (position correction information) described above together with information (satellite identification number) for specifying a plurality of GPS satellites used for obtaining the error information. Is supposed to send. For this reason, a nearby vehicle or the like that has received the error information can determine whether or not the current position obtained from a plurality of GPS satellites received by the navigation device can be corrected using this satellite identification number.

  On the other hand, according to the inter-vehicle communication system of claim 3 of the present invention, the current position specified by the position specifying means is corrected by receiving the error information and the information specifying the satellite transmitted by the transmitting means. Since the position correcting means is provided, it can be corrected to a correct position every time a nearby vehicle receives a beacon signal. Moreover, since this beacon uses an optical beacon of VICS, it is not necessary to construct a new infrastructure, and there is a great practical effect.

Hereinafter, an inter-vehicle communication system according to an embodiment of the present invention will be described with reference to the accompanying drawings. 1 to 3 are examples of embodiments for carrying out the present invention, and the present invention is not limited to these drawings.
FIG. 1 is a main part configuration diagram showing an outline of a configuration of an apparatus main body in a vehicle-to-vehicle communication system according to an embodiment of the present invention. In this figure, reference numeral 1 denotes a navigation device that measures the current position of a vehicle using signals transmitted from a plurality of GPS satellites (not shown in FIG. 1). The navigation device 1 includes a GPS receiver 2 that receives signals transmitted from a plurality of GPS satellites, and calculates the position of the vehicle on which the navigation device 1 is mounted from the signals received by the GPS receiver 2. A GPS position calculation unit 3 to be obtained, a D-GPS reception unit 4 that receives correction information superimposed and transmitted on an FM broadcast radio wave that corrects an error in a measurement position measured by a GPS satellite, the D-GPS reception unit 4 and A position correction processing unit 5 that corrects current position information obtained by the GPS position calculation unit 3 from a GPS position error correction value that will be described later, receives the corrected current position information and the state of surrounding vehicles that will be described later, and generates display information. The display control unit 6 includes a display unit 7 that displays information generated by the display control unit 6 to the passengers of the vehicle.

  On the other hand, in this figure, reference numeral 10 denotes a VICS device that receives road traffic information (VICS beacon). The VICS device 10 includes a VICS receiver 11 and an optical beacon that receive a signal from a VICS projector / receiver 50 that is provided on the road and transmits road traffic information including its position information as an optical beacon, for example, as shown in FIG. Is provided with a VICS position calculation unit 12 for obtaining position information where the light projecting / receiving unit 50 (the controller 51) included in the road traffic information sent by is sent.

  This apparatus main body compares the current position obtained from the navigation apparatus 1 with the position information obtained from the VICS apparatus 10, and the deviation (positioning error) between the current position obtained based on the GPS satellite and the true position. A GPS position error correction calculation unit 20 that calculates error information for correcting the error by calculation is provided. Further, the apparatus main body includes a transmission information processing unit 21 that converts error information obtained by the GPS position error correction calculation unit 20 and positioning data (raw data) measured by the navigation device 1 into a predetermined data format, and a transmission information processing unit. There is provided a wireless communication unit 30 including a transmission unit 31 that transmits a frame converted by 21 to a nearby vehicle (not shown) and a reception unit 32 that receives a frame transmitted from another vehicle. Note that the frequency transmitted and received by the wireless communication unit 30, the transmission output of the transmission unit 31, the type of radio wave, the modulation method, etc., use radio waves regulated by the Radio Law, etc., or weak radio waves not applicable to radio law regulations. There is no particular limitation.

Incidentally, in addition to the error information and positioning data (raw data) described above, the transmission information processing unit 21 also includes various types of information such as vehicle type, company name, color, etc. as vehicle information, latitude / longitude, vehicle speed, etc. as position information. The data format is transmitted through the transmission unit 31.
On the other hand, the frame including the above-described various information transmitted from the own vehicle and the other vehicle is received by the receiving unit 32 and is provided to the reception information processing unit 22 that processes the various information included in this frame. The reception information processing unit 22 has a function of extracting the vehicle information described above in addition to the error information included in the received frame. Then, the obtained error information is given to the position correction processing unit 5 of the navigation device 1 as GPS position error correction information.

Schematically, the vehicle-to-vehicle communication system of the present invention configured as described above will be described with reference to the flowchart shown in FIG.
FIG. 2 is a flowchart showing an operation procedure of the apparatus main body mounted on the vehicle that has received the VICS beacon. First, the VICS receiver 11 determines whether a VICS beacon (optical beacon) has been received (step S1). When it is determined that the VICS receiving unit 11 has received the optical beacon, the VICS position calculation unit 12 includes the positional information included in the optical beacon transmitted by the VICS light projecting / receiving unit 50 (the position of the place where the VICS projecting / receiving unit 50 is disposed). Information) is obtained (step S2). Then, the GPS position error correction calculation unit 20 obtains a GPS position error correction value by obtaining a difference between the VICS position information obtained in step S2 and the GPS position information obtained by the GPS position calculation unit 3 of the navigation device 1 (step S3). ). The obtained position error correction value is converted into a predetermined format by the transmission information processing unit 21 and transmitted to another vehicle via the transmission unit 31 (step S4).

The information sent from the transmission unit 31 as described above is received by the reception unit 32 of the own vehicle and another vehicle (not shown). FIG. 3 is a flowchart showing an operation procedure for correcting the vehicle position based on the error information received by the receiving unit 32.
First, the navigation apparatus 1 mounted on the vehicle receives signals transmitted from a plurality of GPS satellites by the GPS receiver 2 and obtains the current position of the vehicle by the GPS position calculator 3 (step S10). Next, the reception information processing unit 22 determines whether or not the reception unit 32 has received a frame including error information from the own vehicle and another vehicle (not shown) (step S11). The reception information processing unit 22 that has determined that the frame including the error information has been received in step S11 receives the error information included in the frame, and determines whether or not the error information is in the direction in which the host vehicle is traveling (for example, the traveling from now). Whether or not it is error information [correction information] for correcting the true position of the intersection to be performed) (step S12).

  The reception information processing unit 22 that has determined that the error information in the direction of travel in step S12 is included, the received error information is obtained by the navigation device 1 of the own vehicle receiving signals from a plurality of GPS satellites. It is determined by comparing with the satellite number information in the received frame whether or not it coincides with the satellite (step S13). When the reception information processing unit 22 determines in step S13 that the plurality of GPS satellites for which the navigation device 1 of the own vehicle has obtained the current position and the GPS satellites received when the other vehicle generates error information match, This error information is given to the position correction processing unit 5 to correct the current position of the host vehicle (step S14).

  On the other hand, when the reception information processing unit 22 determines in step S11 that the reception unit 32 has not received a frame including error information from the own vehicle and another vehicle (not shown), in step S12, the reception information processing unit 22 is directed to the direction in which the own vehicle will proceed. When it is determined that it is not error information, and it is determined that the error information included in the frame received in step S13 does not match the satellite from which the navigation device 1 of the own vehicle has received signals from a plurality of GPS satellites and obtained the current position. Then, the correction value received by the D-GPS receiver 4 is given to the position correction processor 5 to correct the current position (step S15).

  In step S15, position correction may be further added as follows. When the reception information processing unit 22 determines in step S13 that the plurality of GPS satellites for which the navigation device 1 of the own vehicle has obtained the current position and the GPS satellites received when the other vehicle generates error information do not match. Based on the GPS satellite information used when the other vehicle generates the error information, the current position is again obtained by the navigation device of the own vehicle, and the error information received earlier is given to the position correction processing unit 5 to The current position is corrected (step S15).

The display control unit 6 that has received the vehicle position information with the current position corrected in this way performs correction so that the correct vehicle position is indicated on the map that the display control unit 6 performs display control, and the reception unit. Peripheral vehicle state information indicating the state of the surrounding vehicle (for example, the position and speed of the other vehicle) received by 32 is given to the display unit 7. The display unit 7 provides the various information to the passengers of the vehicle.
Specifically, the vehicle S _T which receives the light beacon sent from the light emitting and receiving unit 50 as shown in FIG. 4 receives the signals transmitted from a plurality of GPS satellites, based on these signals Specify the current location. At this time, as described above, in the case of the GPS standard positioning service SPS, the position may be shifted by about 38 m to 10 m from the true position, and the navigation device 1 that has received the signals transmitted from the same GPS satellites displays them. Although the current position may be outside the road, such as the vehicles S _s and R _s , the inter-vehicle communication system of the present invention can be corrected by the position information transmitted by the VICS optical beacon. That navigation apparatus 1 for a vehicle which receives the light beacon corrects the current vehicle position displaying a S _T is the true position. Vehicle S _T further receiving the light beacon, sends the correction information for correcting the current position identified by the GPS satellites to the vehicle on the periphery. Therefore, the vehicle near that receives this signal can be displayed on the corrected in R _T display unit 7 of the navigation device 1 is true vehicle position from the vehicle position R _s including an error.

  Thus, according to the vehicle-to-vehicle communication system of the present invention described above, the known position information transmitted by the optical beacon arranged in the vicinity of the intersection is received and specified by the position information and signals received from a plurality of GPS satellites. Since the deviation information (error) from the current position is obtained and this error information is transmitted to vehicles existing in the vicinity of the own vehicle, the neighboring vehicles that have received this correction information are installed in the respective navigation systems. System position correction can be performed. This position correction is performed every time a nearby vehicle receives a signal from a beacon. Therefore, even if the GPS satellite position moves or the propagation state of a signal transmitted from the GPS satellite changes. The latest GPS position correction information (error information) can always be transmitted.

  Further, according to the inter-vehicle communication system of the present invention, the error information (position correction information) described above is transmitted together with the information (satellite identification number) for specifying a plurality of GPS satellites used for obtaining the error information described above. It is like that. For this reason, the vehicle or the like that has received the error information determines whether or not the current position obtained from the plurality of GPS satellites received by its navigation device 1 can be corrected using this satellite identification number, and when it can be corrected. Can be corrected to the true vehicle position using the correction information.

Moreover, since the inter-vehicle communication system of the present invention performs position correction using an optical beacon of VICS, it is not necessary to construct a new infrastructure, and a vehicle in an ASV (Advanced Safety Vehicle) using GPS There are practically great effects such as the ability to increase the accuracy of the position.
The inter-vehicle communication system of the present invention is not limited to the above-described embodiment, and various modifications may be made without departing from the gist of the present invention.

  For example, in the inter-vehicle communication system of the present invention, the positioning data (raw data) itself measured by the navigation apparatus 1 is also converted into a predetermined data format by the transmission information processing unit 21 and transmitted. For this reason, even when it is not necessary to perform position correction on the receiving side or when raw data is required, it is applicable.

It is a schematic block diagram which shows the principal part of the vehicle-to-vehicle communication system which concerns on one Embodiment of this invention. It is a flowchart which shows the operation | movement procedure of the transmission information processing part shown in FIG. It is a flowchart which shows the operation | movement procedure of the reception information processing part shown in FIG. It is a figure which shows an example by which the position of the vehicle to which the inter-vehicle communication system which concerns on one Embodiment of this invention is applied is correct | amended to a true position. It is a figure which shows an example of schematic structure of the VICS optical beacon transmission / reception part arrange | positioned in the road vicinity, and its transmission / reception range.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Navigation apparatus 2 GPS receiving part 3 GPS position calculating part 4 D-GPS receiving part 5 Position correction process part 6 Display control part 7 Display part 10 VICS apparatus 11 VICS receiving part 12 VICS position calculating part 20 GPS position error correction calculating part 21 Transmission information processing unit 22 Reception information processing unit 30 Wireless communication unit

Claims (3)

Position identifying means for receiving signals transmitted from a plurality of satellites and identifying the current position based on these signals;
Receiving means for receiving the position information from a beacon provided on the road and transmitting a signal including the installed position information;
Error information calculation means for comparing the position information received by the receiving means and the current position specified by the position specifying means to obtain error information indicating a deviation between the position information and the current position;
A vehicle-to-vehicle communication system comprising transmission means for transmitting the error information calculated by the error information calculation means.   The inter-vehicle communication system according to claim 1, wherein the transmission means further transmits satellite identification information for identifying the plurality of satellites used for specifying the current position. The inter-vehicle communication system according to claim 1 or 2,
A vehicle-to-vehicle communication system comprising: position correction means for receiving the error information transmitted by the transmission means and correcting the current position specified by the position specifying means.

Images