JP2014032545A - Travel support device and travel support method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a travel support device that allows a vehicle group to smoothly travel on a road including a signalized intersection and to provide a travel support method.SOLUTION: An information provision determination device 6 generates vehicle group formation request information for urging driving operation to form a vehicle group. An optical beacon communication unit 4A transmits the vehicle group formation request information. When arriving a communication area of the optical beacon communication unit 4A, an in-vehicle unit 10 mounted on a vehicle Ca receives the vehicle group formation request information, and presents the vehicle group formation request information. A uniform vehicle group formation can be achieved by road-vehicle cooperation.

Description

  The present invention relates to a driving support device and a driving support method for supporting driving of a vehicle, and more particularly to a driving support device and a driving support method for realizing smooth vehicle group driving on a driving road including a signalized intersection.

  Conventionally, as a vehicle group operation management device for realizing smooth vehicle group traveling, for example, there is a technique described in Patent Document 1. This technique controls the blue display time of the traffic lights and the speed of the vehicle group so that the vehicle group in the upward direction and the vehicle group in the downward direction pass through a predetermined intersection in synchronization.

JP 2012-68721 A

However, in the technique described in Patent Document 1, a vehicle group that has already been formed is detected, and traffic light control and vehicle group speed control are performed on the vehicle group. Therefore, the above control cannot be applied to a traffic flow in which no vehicle group is formed, and there is room for improvement in terms of realizing a smooth traffic flow.
Then, this invention makes it a subject to provide the driving assistance apparatus and driving assistance method which implement | achieve smooth vehicle group driving | running | working on the driving road containing a signalized intersection.

  In order to solve the above-described problem, according to one aspect of the present invention, vehicle group formation request information that prompts a driving operation for forming a vehicle group is generated, and the information is installed on a road at an upstream position away from a signalized intersection. Transmitted from the first communication means. The vehicle-mounted device mounted on the vehicle and having a road-to-vehicle communication function receives the driving support information transmitted by the first communication means and presents the driving support information.

  According to the present invention, vehicle group formation request information for encouraging vehicle group formation is transmitted from the road side to the vehicle, and this is presented to the driver on the vehicle side, so uniform vehicle group formation by road-vehicle cooperation is expected. can do. Therefore, it is possible to easily apply control for realizing smooth vehicle group traveling, such as traffic light control and vehicle group speed control.

It is a figure which shows the structure of the system with which the driving assistance device which concerns on this embodiment is applied. It is a figure which shows the structure of a vehicle detector. It is a block diagram which shows the structure of onboard equipment. It is a flowchart which shows the information provision determination reason procedure performed with an information provision determination apparatus. It is a figure explaining the outline of signal control. It is a figure explaining operation in case a target vehicle is at the head of a traffic flow. It is a figure which shows vehicle group detection when a target vehicle exists in the head of a traffic flow. It is a figure explaining the flow to vehicle group formation. It is a figure explaining operation in case a target vehicle exists in a vehicle group. It is a figure explaining operation | movement when there are two or more target vehicles in a vehicle group.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
(Constitution)
FIG. 1 is a diagram illustrating a configuration of a system to which the driving support apparatus according to the present embodiment is applied.
In the figure, reference numeral 1 denotes a roadside infrastructure facility. The roadside infrastructure facility 1 includes a traffic light 2, a signal controller 3, optical beacon communication devices 4A and 4B, vehicle detectors 5A and 5B, and an information provision determination device 6.

The signal controller 3 controls the lamp color state of the signal apparatus 2 and outputs information (lamp color state, lamp color remaining second time, etc.) of the signal apparatus 2 to the information provision determination device 6.
The optical beacon communication device 4A is installed on a road at an upstream position away from a downstream signal intersection in one section between signal intersections. Here, the case where the optical beacon communication device 4A is installed at the outflow portion of the upstream signal intersection in the one section is shown. Also, the optical beacon communication device 4B is installed on the road at the upstream position away from the signal intersection on the downstream side, as with the optical beacon communication device 4A, and on the road downstream from the installation position of the optical beacon communication device 4A.

  These optical beacon communication devices 4A and 4B can communicate with the vehicle-mounted device 10 mounted on the vehicle Ca. The in-vehicle device 10 transmits uplink information including identification information (vehicle ID) for identifying the vehicle Ca to the optical beacon communication devices 4A and 4B. The optical beacon communication devices 4 </ b> A and 4 </ b> B receive the uplink information transmitted by the vehicle-mounted device 10 and transmit the travel support information generated by the information provision determination device 6 to the vehicle-mounted device 10 as downlink information. The driving support information generated by the information provision determination device 6 will be described in detail later.

The vehicle detector 5A is installed in parallel or in parallel with the optical beacon communication device 4A, and senses the traffic flow at its installation position. In addition, the vehicle detector 5B is installed in parallel or in parallel with the optical beacon communication device 4B, and detects the traffic flow at its installation position.
The vehicle detectors 5A and 5B are ultrasonic or optical vehicle detectors, and transmit radio waves and light to the road surface as shown in FIGS. 2 (a) and 2 (b). Measure the time to receive. Then, when the vehicle is present at the measurement point as shown in FIG. 2A and when no vehicle is present at the measurement point as shown in FIG. The presence or absence of a vehicle is determined using the difference. The vehicle detectors 5A and 5B can acquire sensing data such as the head time and speed of a vehicle passing through its own measurement point.

FIG. 3 is a block diagram showing the configuration of the vehicle-mounted device 10.
As shown in FIG. 3, the vehicle-mounted device 10 includes a beacon antenna 11 and a car navigation system 12.
The beacon antenna 11 performs wireless communication using optical waves with the optical beacon communication devices 4A and 4B, and receives information including travel support information. Then, the beacon antenna 11 outputs the received information to the car navigation system 12.

The car navigation system 12 includes a navigation ECU 21, a display 22, and a speaker 23. The navigation ECU 21 is an electronic control unit that is configured around a microcomputer that operates according to a control program.
The navigation ECU 21 includes an optical communication unit 24, a CAN communication unit 25, a processing unit 26, and an HMI control unit 27.
The optical communication unit 24 inputs information from the optical beacon communication devices 4 </ b> A and 4 </ b> B received by the beacon antenna 11 and outputs the information to the processing unit 26.

The CAN communication unit 25 inputs the traveling state of the vehicle Ca such as vehicle speed information, turn signal information (direction indicator operation state), accelerator opening information, brake ON / OFF information, etc. To the unit 26.
The processing unit 26 collects information from the optical communication unit 24 and the CAN communication unit 25. And the process part 26 performs the driving assistance process which assists driving | running | working of the vehicle Ca based on these collected information. For example, the processing unit 26 performs a process of transmitting the travel support information input from the optical communication unit 24 to the HMI control unit 27 as the travel support process.
The HMI control unit 27 outputs the driving support information input from the processing unit 26 to the display 22 and outputs previously prepared audio information to the speaker 23. In this way, the driving support information is presented to the occupant.

Next, an information provision determination process including a driving support information generation process executed by the information provision determination apparatus 6 will be described.
FIG. 4 is a flowchart showing an information provision determination processing procedure executed by the information provision determination device 6.
First, in step S1, the information provision determination device 6 determines whether or not the uplink information from the vehicle-mounted device 10 of the information provision target vehicle Ca (hereinafter also simply referred to as the target vehicle Ca) is received by the optical beacon communication device 4A. judge. If uplink information is not received, the process waits as it is, and when uplink information is received, the process proceeds to step S2.

In step S2, the information provision determination device 6 acquires the uplink information received by the optical beacon communication device 4A, stores it in a memory or the like, and then proceeds to step S3. In step S2, for example, the vehicle ID is stored in association with the reception time of the uplink information.
In step S3, the information provision determination device 6 determines whether or not the target vehicle Ca that has transmitted the uplink information is traveling at the head of the traffic flow. Here, if the vehicle detector 5A detects a vehicle whose head time is less than or equal to a predetermined time before the target vehicle Ca is detected by the vehicle detector 5A, the target vehicle Ca is traveling at the head of the traffic flow. Judge that there is no.

If it is determined in step S3 that the target vehicle Ca is not traveling at the beginning of the traffic flow, the process proceeds to step S4, and if it is determined that the target vehicle Ca is traveling at the beginning of the traffic flow. Shifts to step S5 to be described later.
In step S <b> 4, the information provision determination device 6 generates vehicle group formation request information that prompts a driving operation for forming a vehicle group as the driving support information. This vehicle group formation request information is based on the ideal vehicle group (uniform flow) where vehicles arrive at the intersection uniformly from the normal vehicle group (non-uniform flow) where vehicles randomly arrive at the intersection. It is for forming.

  In this step S4, the vehicle group formation request information is information (inter-vehicle distance holding information) instructing to follow the vehicle while maintaining the inter-vehicle distance with the preceding vehicle. Then, this is set as the downlink information from the optical beacon communication device 4A, and the process proceeds to Step S6 described later. Thereby, 4 A of optical beacon communication apparatuses distribute the said inter-vehicle distance holding information with respect to the onboard equipment 10 of object vehicle Ca.

  In step S5, the information provision determination device 6 generates information regarding the recommended speed of the target vehicle Ca (recommended speed information) as the vehicle group formation request information. In this embodiment, a value obtained by adding a predetermined speed α (several km / h to several tens km / h) set in advance to the regulation speed Vr of the travel route of the target vehicle Ca is set as the recommended speed Vp (Vp = Vr + α). . The value of the recommended speed Vp is stored in advance.

And in this step S5, the information provision determination apparatus 6 sets this recommended speed information as downlink information from the optical beacon communication device 4A. Thereby, 4 A of optical beacon communication apparatuses distribute the said recommended speed information with respect to the onboard equipment 10 of object vehicle Ca.
Next, in step S6, the information provision determination apparatus 6 determines whether the uplink information from the vehicle-mounted device 10 of the target vehicle Ca is received by the optical beacon communication device 4B. If uplink information is not received, the process waits as it is, and when uplink information is received, the process proceeds to step S7.

In step S7, the information provision determination device 6 acquires the uplink information received by the optical beacon communication device 4B, stores it in a memory or the like, and then proceeds to step S8. In step S7 as well, the vehicle ID is stored in association with the reception time of the uplink information in the same manner as in step S2 described above.
In step S8, the information provision determination device 6 calculates the travel time Ta of the target vehicle Ca based on the uplink information stored in step S2 and the uplink information stored in step S7. Specifically, the target vehicle Ca passes through the installation point of the optical beacon communication device 4A based on the vehicle ID included in the uplink information and the reception time of the uplink information stored in association with the vehicle ID. The time from passing through the installation point of the optical beacon communication device 4B is calculated, and this is defined as the travel time Ta between the two points.

Next, in step S9, the information provision determination device 6 determines whether or not the travel time Ta calculated in step S8 is within an allowable range. Here, whether or not the travel time Ta is a time during which it can be determined that the target vehicle Ca is traveling at a speed lower than the speed defined in advance between the two points (traveling around the recommended speed Vp). Determine.
In the present embodiment, the case where it is determined whether or not the travel time Ta of the target vehicle Ca is within the allowable range has been described, but it is determined whether or not the travel speed of the target vehicle Ca is lower than a predetermined speed. You may make it determine directly. In this case, the travel speed of the target vehicle Ca is calculated based on the travel time Ta and the distance from the installation point of the optical beacon communication device 4A to the installation point of the optical beacon communication device 4B.

If it is determined that the target vehicle Ca is traveling at a speed lower than a predetermined speed, the travel time Ta is determined to be within the allowable range, and the process proceeds to step S10. On the other hand, when it is determined that the target vehicle Ca is not traveling at a speed higher than the predetermined speed, the travel time Ta is determined to be outside the allowable range, and the process proceeds to step S13 described later.
In step S10, the information provision determination device 6 generates information (vehicle group maintenance information) that prompts the driving operation for maintaining the vehicle group as the driving support information. Here, the vehicle group maintenance information includes, for example, information for maintaining the current vehicle speed (or recommended vehicle speed Vp), information for maintaining the inter-vehicle distance from the preceding vehicle when there is a preceding vehicle, Information indicating that the vehicle group has been successfully formed by traveling according to the group formation request.

And this vehicle group maintenance information is set as downlink information from the optical beacon communication apparatus 4B, and it transfers to step S11. Thereby, the optical beacon communication device 4B distributes the vehicle group maintenance information to the vehicle-mounted device 10 of the target vehicle Ca.
In step S11, the information provision determination device 6 detects a vehicle group starting with the target vehicle Ca based on the sensing data of the vehicle detector 5B. Here, when the vehicle head time detected by the vehicle detector 5B is less than a preset threshold time (for example, 7 seconds), it is determined that the following vehicle is a vehicle that forms the same vehicle group as the preceding vehicle. Then, as the information on the detected vehicle group, the average speed of the vehicle group, the number of vehicle group components, the vehicle group length (the length from the first vehicle to the last vehicle), and the like are detected.

  Next, in step S12, the information provision determination device 6 performs signal control for controlling the presenting of the traffic signal 2 (front traffic signal) in front of the target vehicle Ca based on the vehicle group information detected in step S10. To end the information provision determination process. Here, as shown in FIG. 5, the signal control starts the green signal of the traffic light 2 with the leading vehicle Ca forming the vehicle group, and the signal of the traffic signal 2 with the last vehicle Cb forming the vehicle group detected in the step S14. This is a process for ending the green light.

  In step S13, the information provision determination device 6 generates vehicle group formation request information. Here, as described in steps S3 to S5, the vehicle group formation request information is recommended speed information when the target vehicle Ca is at the head of the traffic flow, and when the target vehicle Ca is not at the head of the traffic flow. Is the inter-vehicle distance holding information. And this is set as downlink information from the optical beacon communication apparatus 4B, and an information provision determination process is complete | finished. Thereby, the optical beacon communication device 4 </ b> B delivers the recommended speed information to the vehicle-mounted device 10.

(Operation)
Next, the operation of the first embodiment will be described.
First, as shown in FIG. 6, the case where the traffic flow with the target vehicle Ca at the head passes through the optical beacon communication device 4A will be described. It is assumed that this traffic flow is a sparse vehicle group that does not form a uniform vehicle group at the time shown in FIG. In addition, among vehicles forming a traffic flow, the vehicle equipped with the vehicle-mounted device 10 having the road-to-vehicle communication function capable of communicating with the optical beacon communication device 4A is assumed to be only one of the first target vehicles Ca.
When the target vehicle Ca reaches the communication area of the optical beacon communication device 4A, the target vehicle Ca transmits uplink information including the vehicle ID to the optical beacon communication device 4A. When the optical beacon communication device 4A receives this (Yes in step S1 in FIG. 4), the information provision determination device 6 acquires the uplink information received by the optical beacon communication device 4A (step S2).

Further, the vehicle management machine 5A detects the target vehicle Ca almost simultaneously with the transmission of the uplink information to the optical beacon communication device 4A by the target vehicle Ca. Since the target vehicle Ca is at the head of the traffic flow, the vehicle detector 5A does not detect other vehicles before detecting the target vehicle Ca.
Therefore, the information provision determination device 6 determines that the target vehicle Ca is at the head of the traffic flow based on the detection data of the vehicle detector 5A (Yes in step S3). Then, the information provision determination apparatus 6 produces | generates the recommended speed information regarding the recommended speed Vp of the target vehicle Ca as information which accelerates | stimulates formation of a vehicle group (step S5). And the optical beacon communication apparatus 4A transmits this recommended speed information to the target vehicle Ca.

When the vehicle-mounted device 10 of the target vehicle Ca receives the recommended speed information, the vehicle-mounted device 10 presents this to the driver using the display 22 or the speaker 23. For example, as shown in FIG. 6, the recommended speed information is presented using the display of the speed meter. Thus, the driver can recognize that speed adjustment is necessary to form a vehicle group.
When the driver adjusts the speed so as to travel around the recommended speed Vp in response to the recommended speed information, the subsequent vehicle also adjusts the speed in accordance with the traveling speed of the target vehicle Ca at the head. Thereby, the uniform vehicle group which makes the target vehicle Ca the head vehicle is formed.

  Then, as shown in FIG. 7, when the target vehicle Ca reaches the communication area of the optical beacon communication device 4B as it is, the target vehicle Ca transmits uplink information including the vehicle ID to the optical beacon communication device 4B. When the optical beacon communication device 4B receives this (Yes in step S6), the information provision determination device 6 acquires the uplink information received by the optical beacon communication device 4B (step S7).

Then, the information provision determination device 6 determines the optical beacon communication device 4B after the target vehicle Ca passes through the optical beacon communication device 4A based on the uplink information acquired through the optical beacon communication devices 4A and 4B. Travel time Ta to reach is calculated (step S8). At this time, since the target vehicle Ca travels between the installation position of the optical beacon communication device 4A and the installation position of the optical beacon communication device 4B around the recommended speed Vp, the travel time Ta is within an allowable range ( Yes in step S9).
Therefore, the information provision determination device 6 generates information for maintaining the current speed of the target vehicle Ca and information indicating that the formation of the vehicle group has been successful as information for maintaining the vehicle group (step S10). And the optical beacon communication apparatus 4B transmits this vehicle group maintenance information with respect to the object vehicle Ca.

  When the vehicle-mounted device 10 of the target vehicle Ca receives the vehicle group maintenance information, the vehicle-mounted device 10 presents this to the driver using the display 22 and the speaker 23. For example, as shown in FIG. 7, information for maintaining the current vehicle speed is presented using a speedometer display. Accordingly, the driver can recognize that the vehicle group formation can be realized by adjusting the speed of the host vehicle. In addition, since information can be provided with a push to maintain the vehicle group, the vehicle group can be prevented from being disturbed in front of the front traffic light.

  When the vehicle group starting from the target vehicle Ca passes directly below the vehicle sensor 5B, the vehicle sensor 5B detects each vehicle forming the vehicle group. That is, almost simultaneously with the transmission of the uplink information to the optical beacon communication device 4B by the target vehicle Ca, the vehicle detector 5B detects the target vehicle Ca that is the first vehicle in the vehicle group. Thereafter, a plurality of vehicles (seven vehicles in the example of FIG. 7) whose vehicle head time is less than a preset threshold time (for example, 7 seconds) are detected. After detecting the last vehicle Cb in the vehicle group, the vehicle sensor 4B does not detect the vehicle for the threshold time or longer.

  Therefore, the information provision determination device 6 detects a vehicle group starting from the target vehicle Ca indicated by the two-dot chain line in FIG. 7 based on the sensing data of the vehicle sensor 5B, and the average speed of the vehicle group is detected. Then, vehicle group information such as the number of vehicle groups and the length of the vehicle group is detected (step S11). And the information provision determination apparatus 6 controls a signal display so that the said vehicle group can pass the front traffic signal 2 with a green signal based on the detected vehicle group information (step S12). Specifically, the green light is started in accordance with the arrival of the leading vehicle Ca at the front traffic light 2 and the green light is terminated in accordance with the passage of the front traffic light 2 of the last vehicle Cb.

In this way, information that prompts the target vehicle Ca to form a vehicle group at an upstream position away from the signalized intersection is provided, and the front traffic signal 2 is stopped for the target vehicle Ca that has traveled in accordance with the vehicle group formation request information. Give the incentive (running privilege) that you can pass without. Therefore, the act of cooperating with the formation of the vehicle group of the driver who has received the vehicle group formation request can be promoted.
In order to realize signal control in accordance with the arrival / passage of the vehicle group, it is necessary to detect the vehicle group appropriately. As shown in FIG. 8 (a), when a sparse vehicle group is formed and a plurality of vehicles are traveling, the vehicle group detection cannot be performed properly and signal control cannot be applied. .

  On the other hand, in this embodiment, as shown in FIG.8 (b), the information regarding the recommended speed Vp of the target vehicle Ca is shown as a vehicle group formation request | requirement with respect to the target vehicle Ca in the head of a traffic flow. At this time, when the driver who has received the vehicle group formation request adjusts the speed and travels the target vehicle Ca at the recommended speed Vp, the target vehicle Ca becomes a pacemaker, as shown in FIG. A variety of vehicles are formed.

  As a result, as shown in FIG. 8D, it is possible to appropriately detect the leading vehicle Ca and the last vehicle Cb that form the vehicle group, and to appropriately detect the vehicle group indicated by the two-dot chain line. it can. Therefore, it is possible to realize signal control in accordance with arrival / passage of the vehicle group based on the detected vehicle group information. That is, by applying this system, a normal vehicle group in which vehicles randomly arrive at the intersection can be made a uniform vehicle group in which vehicles arrive at the intersection at the next intersection. Thus, by forming a vehicle group by road-vehicle cooperation, appropriate signal control can be performed. As a result, smooth vehicle group traveling can be realized, and it can be expected that traffic congestion will be eliminated.

Next, the case where the traffic flow passes through the optical beacon communication device 4A in a state where the target vehicle Ca on which the vehicle-mounted device 10 is mounted is not at the head of the traffic flow (a state where the vehicle is in the traffic flow) will be described.
In this case, the vehicle detector 5A detects the other vehicle before detecting the target vehicle Ca. Therefore, the information provision determination device 6 determines that the target vehicle Ca is not at the head of the traffic flow based on the detection data of the vehicle detector 5A (No in step S3). Then, the information provision determination apparatus 6 produces | generates the information for hold | maintaining the distance between vehicles with a preceding vehicle as information which accelerates | stimulates formation of a vehicle group (step S4). Then, the optical beacon communication device 4A transmits this inter-vehicle distance holding information to the target vehicle Ca.

When the vehicle-mounted device 10 of the target vehicle Ca receives the inter-vehicle distance holding information, the vehicle-mounted device 10 presents this to the driver using the display 22 and the speaker 23. Thus, the driver can recognize that it is necessary to maintain the inter-vehicle distance from the preceding vehicle in order to form the vehicle group.
When the driver of the target vehicle Ca receives the inter-vehicle distance holding information and adjusts the speed so as to maintain the inter-vehicle distance from the preceding vehicle, the subsequent vehicle also adjusts the speed in accordance with the target vehicle Ca. Thereby, as shown in FIG. 9, at least in the lane in which the target vehicle Ca travels, a uniform vehicle group including the target vehicle Ca is formed.

Then, when the target vehicle Ca reaches the communication area of the optical beacon communication device 4B as it is, the target vehicle Ca transmits uplink information to the optical beacon communication device 4B, and the information provision determination device 6 uses the optical beacon communication device 4B. The uplink information is acquired via (step S7).
Then, the information provision determination apparatus 6 calculates the travel time Ta of the target vehicle Ca based on the uplink information acquired via the optical beacon communication devices 4A and 4B (step S8). At this time, when the preceding vehicle of the target vehicle Ca is traveling at around the recommended speed Vp, the traveling speed of the target vehicle Ca traveling at a certain distance from the preceding vehicle is also around the recommended speed Vp. Become. Therefore, in this case, the travel time Ta of the target vehicle Ca is within the allowable range (Yes in step S9).

  Therefore, the information provision determination apparatus 6 produces | generates the information for hold | maintaining the inter-vehicle distance with a preceding vehicle as it is as information for maintaining a vehicle group (step S10). And the optical beacon communication apparatus 4B transmits this vehicle group maintenance information with respect to the object vehicle Ca. When the vehicle-mounted device 10 of the target vehicle Ca receives the vehicle group maintenance information, the vehicle-mounted device 10 presents the vehicle group maintenance information to the driver using the display 22 and the speaker 23. For example, as shown in FIG. 9, information for maintaining the current vehicle speed is presented using the display of the speedometer.

  Next, the information provision determination device 6 detects a vehicle group starting from the target vehicle Ca indicated by a two-dot chain line in FIG. 9 based on the sensing data of the vehicle detector 5B, and the average speed of the vehicle group is detected. Then, vehicle group information such as the number of vehicle groups and the length of the vehicle group is detected (step S11). And the information provision determination apparatus 6 controls a signal display so that the said vehicle group can pass the front traffic signal 2 with a green signal based on the detected vehicle group information (step S12).

  In this way, when the target vehicle Ca is in a traffic flow, by presenting information that holds the inter-vehicle distance from the preceding vehicle as information that prompts the formation of the vehicle group, Formation can be expected. Therefore, the vehicle group can be detected appropriately, and signal control in accordance with arrival / passage of the vehicle group can be realized. At this time, since signal control is applied to the vehicle group with the target vehicle Ca as the leading vehicle, the target vehicle Ca that cooperated with the formation of the vehicle group can reliably pass without stopping at the front traffic light.

  Next, the case where the traffic flow passes through the optical beacon communication device 4A in a state where a plurality of (three in this case) target vehicles Ca1 to Ca3 mounted with the vehicle-mounted device 10 are in the traffic flow will be described. Here, it is assumed that the target vehicles Ca1 to Ca3 are not at the head of the traffic flow and are arranged in the order of the target vehicle Ca1, the target vehicle Ca2, and the target vehicle Ca3 from the head side of the traffic flow. The target vehicle Ca3 is assumed to be the last vehicle in the traffic flow.

  In this case, the information provision determination device 6 determines that the target vehicles Ca1 to Ca3 are not at the head of the traffic flow based on the detection data of the vehicle detector 5A (No in step S3). Therefore, the information provision determination device 6 generates inter-vehicle distance holding information as information for prompting the formation of the vehicle group (step S4), and the optical beacon communication device 4A uses this on-vehicle device 10 of the target vehicles Ca1 to Ca3. As downlink information for.

  When the in-vehicle devices 10 of the target vehicles Ca1 to Ca3 receive the inter-vehicle distance holding information, each on-vehicle device 10 presents the inter-vehicle distance holding information to each driver using the display 22 and the speaker 23. At this time, when the vehicle distance holding information is received and only the driver of the target vehicle Ca2 and the target vehicle Ca3 adjusts the speed so as to maintain the distance between the preceding vehicles, the target vehicle Ca2 as shown in FIG. And a uniform vehicle group including the target vehicle Ca3.

  When the target vehicle Ca1 reaches the communication area of the optical beacon communication device 4B as it is, the information provision determination device 6 is based on the uplink information from the target vehicle Ca1 acquired via the optical beacon communication devices 4A and 4B, respectively. The travel time Ta of the target vehicle Ca1 is calculated (step S8). At this time, when the target vehicle Ca1 is traveling at a speed that is significantly higher than the recommended speed Vp, the travel time Ta of the target vehicle Ca1 is outside the allowable range (No in step S9).

Therefore, the information provision determination device 6 generates inter-vehicle distance holding information as information for prompting formation of a vehicle group (step S13). And the optical beacon communication apparatus 4B transmits this inter-vehicle distance holding information to the target vehicle Ca1. For example, as shown in FIG. 10, a speed meter display is used to indicate that speed adjustment is necessary to maintain the inter-vehicle distance. That is, the vehicle group formation request is transmitted again to the driver of the target vehicle Ca1.
As described above, in the case where the driver does not follow the vehicle group formation request despite the transmission of the vehicle group formation request from the optical beacon communication device 4A to the target vehicle Ca1, the target vehicle is again realized. A vehicle group formation request can be transmitted to Ca1.

  Thereafter, when the target vehicle Ca2 reaches the communication area of the optical beacon communication device 4B, the information provision determination device 6 similarly calculates the travel time Ta of the target vehicle Ca2 (step S8). At this time, if the target vehicle Ca2 is traveling around the recommended speed Vp and the travel time Ta of the target vehicle Ca2 is within the allowable range (Yes in step S9), a vehicle group is formed for the target vehicle Ca2. The vehicle group maintenance information including information indicating that the vehicle has been successfully operated is provided. For example, as shown in FIG. 10, information for maintaining the current vehicle speed is presented using the display of the speedometer. The same applies to the target vehicle Ca3.

Therefore, in this case, the information provision determination device 6 detects a vehicle group starting from the target vehicle Ca2 indicated by the two-dot chain line in FIG. 10 based on the sensing data of the vehicle detector 5B, and Vehicle group information such as the average speed of the group, the number of vehicle group members, and the vehicle group length is detected (step S11). As described above, when there are a plurality of target vehicles whose travel time Ta is within the allowable range in the vehicle group, the vehicle group starting from the target vehicle at the head (here, the target vehicle Ca2) is detected. To do. And the information provision determination apparatus 6 controls a signal display so that the said vehicle group can pass the front traffic signal 2 with a green signal based on the detected vehicle group information (step S12).
Thus, when there are a plurality of target vehicles in the traffic flow, the vehicle group formation request information is transmitted from the optical beacon communication device 4A to all the target vehicles. Then, the travel time Ta is determined for all the target vehicles that have transmitted the vehicle group formation request information, and an incentive is surely given to the target vehicle whose travel time Ta is within the allowable range.

In FIG. 1, the optical beacon communication device 4A corresponds to the first communication means, the optical beacon communication device 4B corresponds to the second communication means, the vehicle detector 5A corresponds to the first vehicle detector, and the vehicle detection. The device 5B corresponds to the second vehicle detector. Moreover, in FIG. 3, the beacon antenna 11 and the car navigation system 12 correspond to information presenting means.
Further, in FIG. 4, steps S4 and S5 correspond to the vehicle group formation request information generation means, step S8 corresponds to the travel time calculation means, and steps S9 to S12 correspond to the specific provision means. Step S10 corresponds to vehicle group maintenance information generation means, step S11 corresponds to vehicle group detection means, and step S12 corresponds to signal control means.

(effect)
In the first embodiment, the following effects can be obtained.
(1) The information provision determination device 6 generates vehicle group formation request information that prompts a driving operation for forming a vehicle group, and the optical beacon communication device 4A transmits this. And the onboard equipment 10 mounted in the vehicle Ca receives the vehicle group formation request information transmitted by the optical beacon communication device 4A, and presents the vehicle group formation request information.
Thus, the vehicle group formation request information transmitted from the optical beacon communication device 4A installed on the roadside is received by the vehicle-mounted device 10 and presented to the driver. Thus, the driver who receives the vehicle group formation request information is urged to perform a driving operation for forming the vehicle group. Therefore, uniform vehicle group formation by road-vehicle cooperation can be realized.

(2) The information provision determination device 6 generates information on the recommended speed Vp (= Vr + α) of the vehicle Ca as the vehicle group formation request information.
As a result, the driver who has received the vehicle group formation request can appropriately recognize the vehicle speed information for forming the vehicle group. In addition, since the recommended speed Vp of the vehicle Ca is set to a speed according to the regulation speed Vr, when the vehicle Ca travels at the recommended speed Vp, it is easy for subsequent vehicles to follow this and to form a uniform vehicle group. .

(3) When the information provision determination device 6 determines that the vehicle Ca is a non-leading vehicle in the traffic flow based on the sensing data of the vehicle detector 5A, the information providing determination device 6 uses the preceding vehicle of the vehicle Ca as the vehicle group formation request information. Information for maintaining the inter-vehicle distance between the two is generated.
In this way, when the vehicle Ca is in a traffic flow, the inter-vehicle distance from the preceding vehicle is held as the vehicle group formation request information in consideration that the speed adjustment may not be performed freely. Send information for. If the distance between the vehicle Ca and the preceding vehicle is kept constant, it can be expected that the following vehicle follows the vehicle while keeping a constant distance between the vehicles. Therefore, the vehicle Ca can be a pacemaker to form a vehicle group.

(4) The vehicle-mounted device 10 transmits uplink information including identification information (vehicle ID) of the vehicle Ca, and the optical beacon communication devices 4A and 4B receive this when the vehicle Ca reaches its own communication area. Receive. The information provision determination device 6 calculates the travel time Ta of the vehicle Ca based on the vehicle ID received by the optical beacon communication devices 4A and 4B. And the information provision determination apparatus 6 gives a travel privilege with respect to the vehicle Ca, when the calculated travel time Ta exists in the tolerance | permissible_range.
Thus, by determining the travel time Ta between the installation position of the optical beacon communication device 4A and the installation position of the optical beacon communication device 4B, the driver who has received the vehicle group formation request information It is possible to confirm whether the driving operation has been performed according to the request. And incentive is given with respect to the object vehicle Ca which performed driving operation according to the vehicle group formation request. Thereby, the act of cooperating with the formation of the driver's vehicle group can be promoted.

(5) When the travel time Ta of the vehicle Ca is within the allowable range, the information provision determination device 6 detects a vehicle group starting from the vehicle Ca based on the sensing data of the vehicle sensor 5B. And the information provision determination apparatus 6 performs signal control as a travel privilege of the vehicle Ca so that the vehicle group heading the vehicle Ca can pass the front traffic light in blue.
Thus, since the vehicle group formed by road-vehicle cooperation is signal-controlled so that it can pass by a green signal without stopping at the front traffic light 2, smooth vehicle group traveling can be realized.

(6) The information provision determination device 6 generates vehicle group maintenance information that prompts a driving operation for maintaining the vehicle group, and the optical beacon communication device 4B has the travel time Ta of the vehicle Ca within an allowable range. The vehicle group maintenance information is transmitted. And the vehicle equipment 10 mounted in vehicle Ca receives the vehicle group maintenance information which the optical beacon communication apparatus 4B transmitted, and presents the said vehicle group maintenance information.
Thus, since the information for maintaining the formed vehicle group is presented to the vehicle Ca that has been operated according to the vehicle group formation request, it is possible to suppress the formed vehicle group from being disturbed in front of the front traffic light 2. can do. Therefore, it is possible to appropriately perform signal control in accordance with arrival / passage of the vehicle group.

(7) The information provision determination device 6 generates information for maintaining the current vehicle speed of the vehicle Ca as the vehicle group maintenance information.
Thereby, it can suppress appropriately that the formed vehicle group is disturbed.
(8) The information provision determination device 6 transmits the vehicle group formation request information when the travel time Ta of the vehicle Ca is outside the allowable range. And the vehicle equipment 10 mounted in the vehicle Ca receives the vehicle group formation request information transmitted from the optical beacon communication device 4B, and presents the vehicle group maintenance information.
In this way, the vehicle group formation request information is presented again to the vehicle Ca that is not operating according to the vehicle group formation request. Therefore, the realization rate of vehicle group formation can be improved.

(9) Generate vehicle group formation request information that prompts a driving operation for forming a vehicle group, and transmit the vehicle group formation request information from a communication device installed on a road upstream from the signalized intersection. And the onboard equipment mounted in a vehicle and having a road-to-vehicle communication function receives the vehicle group formation request information transmitted by the communication device and presents it.
Thus, the vehicle group formation request information transmitted from the roadside is received by the vehicle-mounted device 10 and presented to the driver. Thus, the driver who receives the vehicle group formation request information is urged to perform a driving operation for forming the vehicle group. Therefore, uniform vehicle group formation by road-vehicle cooperation can be realized.

(Modification)
(1) In the above-described embodiment, the case where the optical beacon communication device 4A and the vehicle detector 5A are installed at the outflow portion of the signal intersection has been described. Can be selected. However, since it is necessary to form a uniform vehicle group from the time when the target vehicle Ca receives the vehicle group formation request until it reaches the front traffic light 2, a distance required for the formation of the uniform vehicle group is ensured. Like that.

(2) In the above embodiment, as shown in FIG. 6, when the target vehicle Ca is in front of the stop line of the traffic light 2, the vehicle-mounted device 10 is added to the vehicle group formation request information from the optical beacon communication device 4A. If the light color state of the traffic light 2 can be received, the following processing can also be performed.
For example, when the target vehicle Ca is at the head of the traffic flow and is waiting for a red light in front of the stop line of the traffic light 2, the on-vehicle device 10 is combined with recommended speed information that is vehicle group formation request information, Presents sudden start suppression information for suppressing sudden start. Thereby, the sudden start of the target vehicle Ca when the traffic light 2 is switched from the red signal to the blue signal can be suppressed, and the formation of the vehicle group starting from the target vehicle Ca can be more reliably performed.

  (3) In the above embodiment, when the target vehicle Ca passes through the optical beacon communication device 4A, if it can be determined that the target vehicle Ca is traveling at the end of the traffic flow, the optical beacon communication device It is possible not to transmit the vehicle group formation request information from 4A. This is because, even if the target vehicle Ca performs speed adjustment to form a vehicle group, there is no subsequent vehicle, and therefore a vehicle group starting from the target vehicle Ca cannot be formed. Here, whether or not the target vehicle Ca is traveling at the end of the traffic flow is determined based on the sensing data of the vehicle detector installed upstream of the installation position of the optical beacon communication device 4A. Thereby, unnecessary information provision can be prevented, and the driver's troublesomeness can be reduced.

  DESCRIPTION OF SYMBOLS 1 ... Roadside infrastructure equipment, 2 ... Traffic light, 3 ... Signal controller, 4A, 4B ... Optical beacon communication device, 5A, 5B ... Vehicle detector, 6 ... Information provision determination apparatus, 10 ... Onboard equipment, 11 ... Beacon antenna, DESCRIPTION OF SYMBOLS 12 ... Car navigation system, 21 ... Navigation ECU, 22 ... Display, 23 ... Speaker, 24 ... Optical communication part, 25 ... CAN communication part, 26 ... Processing part, 27 ... HMI control part

Claims (9)

A driving support device that supports driving of a vehicle,
Vehicle group formation request information generating means for generating vehicle group formation request information for prompting a driving operation for forming a vehicle group;
A first communication unit installed on a road at an upstream position away from the signalized intersection and transmitting the vehicle group formation request information generated by the vehicle group formation request information generation unit;
An on-vehicle device mounted on the vehicle and having a road-to-vehicle communication function,
The vehicle-mounted device includes an information presentation unit that receives the vehicle group formation request information transmitted by the first communication unit and presents the vehicle group formation request information. The vehicle group formation request information generating means
The travel support apparatus according to claim 1, wherein the vehicle group formation request information includes information related to a recommended speed set in advance based on a regulation speed of a travel route of the vehicle. A first vehicle detector installed in the vicinity of the installation position of the first communication means for sensing traffic flow at the installation position;
The vehicle group formation request information generating means
When it is determined that the vehicle is a non-leading vehicle in the traffic flow based on the sensing data of the first vehicle sensor, an inter-vehicle distance from the preceding vehicle of the vehicle is held as the vehicle group formation request information The driving support device according to claim 1, wherein information for generating the driving information is generated. The on-vehicle device transmits the identification information of the vehicle on which it is mounted,
The first communication means can receive the identification information transmitted by the vehicle-mounted device,
A second communication means installed on the road at a position upstream from the signalized intersection and downstream from the installation position of the first communication device, and capable of receiving the identification information transmitted by the vehicle-mounted device;
Travel time calculating means for calculating the travel time of the vehicle based on the vehicle identification information received by the first communication means and the second communication means;
4. A privilege providing unit that gives a travel privilege to the vehicle when the travel time calculated by the travel time calculation unit is within an allowable range. 5. The driving support apparatus according to the description. A second vehicle detector installed in the vicinity of the installation position of the second communication means for sensing traffic flow at the installation position;
The privilege providing means is:
Vehicle group detection means for detecting a vehicle group starting from the vehicle based on the sensing data of the second vehicle sensor when the travel time calculated by the travel time calculation means is within an allowable range;
The signal control means for performing signal control for controlling the signal display so that the vehicle group detected by the vehicle group detection means can pass through the signal intersection with a green light as the travel privilege. 4. The driving support device according to 4. Vehicle group maintenance information generating means for generating vehicle group maintenance information for prompting a driving operation for maintaining the vehicle group;
When the travel time calculated by the travel time calculation means is within an allowable range, the second communication means transmits the vehicle group maintenance information generated by the vehicle group maintenance information generation means,
6. The travel support according to claim 4, wherein the information presentation unit of the vehicle-mounted device receives the vehicle group maintenance information transmitted from the second communication unit and presents the vehicle group maintenance information. apparatus. The vehicle group maintenance information generating means
The travel support apparatus according to claim 6, wherein information for maintaining a current vehicle speed of the vehicle is generated as the vehicle group maintenance information. The second communication means transmits the vehicle group formation request information generated by the vehicle group formation request information generation means when the travel time calculated by the travel time calculation means is outside an allowable range,
The information presentation unit of the on-vehicle device receives the vehicle group formation request information transmitted by the second communication unit and presents the vehicle group formation request information. The driving support device according to Item 1. A driving support method for supporting driving of a vehicle,
Generate vehicle group formation request information that prompts driving operations to form a vehicle group, and transmit the vehicle group formation request information from a communication device installed on the road upstream from the signalized intersection,
An on-vehicle device mounted on the vehicle and having a road-to-vehicle communication function receives and presents the vehicle group formation request information transmitted by the communication device.

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