JP5397364B2 - Multi-vehicle group driving support device - Google Patents

Description

The present invention relates to a group travel support device, and more particularly to a device that acquires travel information of other vehicles in a group and supports group travel based on the travel information.

As devices for supporting group traveling of a plurality of vehicles, for example, devices described in Japanese Patent Application Laid-Open No. 2000-33284 (Patent Document 1) and Japanese Patent Application Laid-Open No. 2001-317953 (Patent Document 2) have been proposed.

In the device proposed in the above Japanese Patent Laid-Open No. 2000-33284, each vehicle in the same group transmits the position of the own vehicle acquired by the GPS system to a server by a mobile phone or the like, and the navigation system of each vehicle The position of the vehicle in the group is displayed.

Further, the device proposed in the above-mentioned Japanese Patent Application Laid-Open No. 2001-317953 inputs a destination to a navigation system of a leading vehicle and transmits a calculated recommended route to the subsequent vehicle.

JP 2000-33284 A JP 2001-317953 A

However, what is proposed in Japanese Patent Laid-Open No. 2000-33284 is based on the premise that each vehicle belonging to a group includes a display device capable of displaying a map. A display device that can display a map is expensive, and this technology cannot be applied to a vehicle that does not include such a display device.

In addition, what is proposed in the above Japanese Patent Application Laid-Open No. 2001-317953 is based on the premise that the leading vehicle has a recommended route calculation function, but the leading vehicle does not have a recommended route calculation function. Cannot apply this technique. Moreover, when the leading vehicle travels on a road different from the recommended route, accurate information cannot be transmitted, and the following vehicle cannot follow.

The group travel support apparatus according to the present invention includes a transmission / reception means for transmitting / receiving vehicle travel status information, a course change determination means for determining a course change of the vehicle that has transmitted the travel status information, based on the travel status information received by the transmission / reception means, And determination result presenting means for presenting a determination result by the course change determining means to the occupant.

According to the present invention, the transmitting station vehicle only needs to transmit the traveling state information, and it is not necessary to calculate the recommended route. Therefore, the configuration of the group traveling support device can be simplified. The receiving station vehicle that has received the driving status information only needs to determine and output the route change of the transmitting station vehicle, and does not need to be displayed on the map. This also simplifies the configuration of the host vehicle of the group driving support device. Can be. With such a simple configuration, it is possible to know the route change of the transmitting station vehicle by the own vehicle, so if the receiving station vehicle is a subsequent vehicle, it is easy to follow the transmitting station vehicle that is the preceding vehicle. If the receiving station vehicle is a preceding vehicle, it is possible to easily know whether or not the transmitting station vehicle that is the succeeding vehicle is following.

It is a block diagram which shows the structural example of the group travel assistance apparatus by 1st Embodiment. It is a flowchart which shows the process sequence of the group travel assistance apparatus by 1st Embodiment. It is a figure which shows the example of the display output to the monitor 30 when it determines with a right turn. It is a figure which shows the example of the display output to the monitor 30 when it determines with a lane change on the right. It is a figure which shows the example of the display output to the monitor 30 when it determines with a left turn. It is a figure which shows the example of the display output to the monitor 30 when it determines with a lane change on the left. It is a flowchart which shows the process sequence of the group travel assistance apparatus by the modification of 1st Embodiment. It is a block diagram which shows the structural example of the group travel assistance apparatus by 2nd Embodiment. It is a flowchart which shows the process sequence of the group travel assistance apparatus by 2nd Embodiment. It is a block diagram which shows the structural example of the group travel assistance apparatus by 3rd Embodiment. It is a flowchart which shows the process sequence of the group travel assistance apparatus by 3rd Embodiment. It is a flowchart which shows the process sequence of the group travel assistance apparatus by the modification of 3rd Embodiment.

<1-1. Configuration of First Embodiment (FIG. 1)>
FIG. 1 is a block diagram showing a configuration example of a group travel support apparatus according to the first embodiment of the present invention. In this group travel support device, the direction indicator sensor 71, the steering angle sensor 72, the vehicle speed sensor 73, and the transceiver 20 are connected to the processing unit 110, and the other vehicle information memory 40, the icon memory 60, and the monitor 30 are connected. Connected and configured. Among them, the processing unit 110 includes a route change determination unit 50 in addition to the control unit 10 and the vehicle information acquisition unit 100.

The direction indicator sensor 71, the steering angle sensor 72, the vehicle speed sensor 73, the transceiver 20, the control unit 10, and the vehicle information acquisition unit 100 are preferably provided particularly on the vehicle on the traveling scene information transmission side. On the other hand, the transmitter / receiver 20, the other vehicle information memory 40, the icon memory 60, the monitor 30, the processing unit 10, and the course change determination unit 50 particularly determine the course change of the other vehicle by receiving the traveling scene information of the other vehicle. It is desirable to be provided in a vehicle on the receiving side. However, it is most desirable that both the vehicles have these configurations so that the traveling scene information can be transmitted and received, and each can determine the course change of the partner vehicle.

Here, the traveling scene information is information (traveling state information) indicating the driving state and the traveling state of the vehicle obtained from the direction indicator sensor 71, the steering angle sensor 72, and the vehicle speed sensor 73. The course change of the vehicle is determined based on the information. That is, it is determined whether the vehicle has made a right or left turn or a lane change based on the travel status information.

<1-2. Details of configuration for acquiring and transmitting / receiving traveling scene information>
The control unit 10 includes a microprocessor and its peripheral circuits, and performs processing of information transmitted / received by the transmitter / receiver 20, processing of information output by the monitor 30, and other controls, and controls the group travel support apparatus according to the present embodiment. It governs the whole.

The vehicle information acquisition unit 100 acquires travel scene information of the host vehicle, and includes a vehicle signal acquisition unit 70 in the first embodiment.

The direction indicator sensor 71 acquires blinker information at a predetermined timing and sends it to the vehicle signal acquisition unit 70. The winker information includes, in particular, information that the driver of the vehicle has operated the turn indicator to release the winker, information that the winker has expired, and information that indicates which of the left and right winkers have been output.

The steering angle sensor 72 acquires the steering angle information at a predetermined timing corresponding to the driver's steering wheel operation, and sends it to the vehicle signal acquisition unit 70.

The vehicle speed sensor 73 acquires vehicle speed information at a predetermined timing and sends it to the vehicle signal acquisition unit 70.

The vehicle signal acquisition unit 70 acquires vehicle signals from the direction indicator sensor 71, the steering angle sensor 72, and the vehicle speed sensor 73 as traveling scene information of the host vehicle, and sends the vehicle signals to the control unit 10.

The transceiver 20 transmits traveling scene information of the host vehicle and / or receives traveling scene information of other vehicles based on control by the control unit 10. Although the specific method of transmission / reception is not particularly limited, narrow-area wireless communication such as a wireless LAN is particularly preferable in terms of reducing communication costs. In addition, it is also possible to use wide area wireless communication such as a mobile phone or PHS.

<1-3. Details of the configuration for judging and outputting the course change>
The other vehicle information memory 40 stores traveling scene information of other vehicles received by the transceiver 20 based on control by the control unit 10. For example, the traveling scene information of other vehicles may be sequentially deleted after a certain time has elapsed after reception, or may be sequentially deleted after the subsequent vehicle has passed a point where the preceding vehicle has passed.

The course change determination unit 50 determines the course change of the other vehicle based on the traveling scene information of the other vehicle stored in the other vehicle information memory 40. The course change here is, for example, a determination of whether the vehicle has made a right / left turn or a lane change.

The icon memory 60 is a memory in which an icon for displaying the determination result by the course change determination unit 50 as an icon is stored in advance, and can be read out based on control by the control unit 10. For example, other vehicle icons and direction indicator icons for displaying traveling scene information of other vehicles, and a host vehicle icon and a route change display icon for displaying a route change determination result are stored.

The monitor 30 is a device that outputs the determination result by the course change determination unit 50 by displaying it based on the control by the control unit 10. However, the output of the determination result is not limited to the display on the monitor, but may be performed by lighting a lamp (not shown) or outputting sound by a speaker (not shown).

<1-4. Action of First Embodiment (FIGS. 2 to 6)>
FIG. 2 is a flowchart showing a processing procedure of the group travel support apparatus according to the first embodiment. In this flowchart, processing in a receiving vehicle (receiving station vehicle) that receives travel scene information acquired and transmitted in another vehicle and determines a course change of the other vehicle will be described. When the direction indicator is operated in the transmission side vehicle (transmission station vehicle) which is another vehicle, the vehicle information acquisition unit 100 of the transmission side vehicle, for example, once a second, blinker information, steering angle information, vehicle speed. Travel scene information such as information is acquired and transmitted to the vehicle on the receiving side via the transmission / reception unit 20. The vehicle on the receiving side receives the traveling scene information from the other vehicle at any time by the transmitter / receiver 20.

In the following description, the case where the transmitting vehicle as the other vehicle is the preceding vehicle and the receiving vehicle as the own vehicle is the subsequent vehicle will be described, but conversely, the transmitting vehicle as the other vehicle is Even if the receiving vehicle that is the succeeding vehicle or the host vehicle is the preceding vehicle, it is still possible to determine the course change of the other vehicle based on the traveling scene information of the other vehicle and output the result.

First, in step S110, when the receiving vehicle receives the operation information of the direction indicator in the other vehicle by the transmitter / receiver 20, the control unit 10 of the receiving vehicle determines the preparation state for determining the course change of the other vehicle. Become. As specific processing of the ready state, in step S120, storage of other vehicle travel scene information in the other vehicle information memory 40 is started. Further, by increasing the frequency of communication with the other vehicle in the transceiver 20 (for example, once a second), information is acquired at a high frequency in preparation for the course change of the other vehicle, and a quick and accurate course change determination is performed. It is desirable to expect.

Furthermore, in step S <b> 130, the control unit 10 of the vehicle on the receiving side outputs the information on the direction indicator received from the other vehicle to the monitor 30. As a specific example of the output, for example, an icon indicating another vehicle is displayed on the monitor 30, and when the right direction indicator is in operation, the direction indicator icon blinks on the right shoulder of the icon indicating the other vehicle, and the left direction While the indicator is in operation, the direction indicator icon blinks on the left shoulder of the icon indicating the other vehicle. Thereby, the user of the receiving vehicle can know which direction indicator the other vehicle is emitting.

Next, in step S140, when information indicating that the operation of the direction indicator in the other vehicle has been completed is received by the transmitter / receiver 20 of the receiving vehicle, in step S150, the course change determining unit 50 of the receiving vehicle determines that the other vehicle has changed. Determine the course change. Here, the determination of the course change is a determination as to whether it is a right / left turn or a lane change.

Specifically, first, based on the winker information and the vehicle speed information of the other vehicle stored in the other vehicle information memory 40, the operation time of the direction indicator and the vehicle speed change amount of the other vehicle during the operation of the direction indicator are determined. Calculate the maximum value. And, for example, the first condition that the maximum value of the vehicle speed change amount while the right direction indicator of the other vehicle is operating is a certain value or more, for example, 20 km / h or more, and the operation of the right direction indicator When the second condition that the time is equal to or longer than a certain time, for example, 5 seconds or longer is satisfied, it is determined that the turn is right. On the other hand, if the maximum value of the vehicle speed change amount during the operation of the right direction indicator is less than 20 km / h and the operation time is less than 5 seconds, it is determined that the lane is changed to the right.

When either one of the first condition and the second condition is not satisfied, it is determined that the vehicle is neither turning left or right nor changing the lane.

Next, in step S <b> 160, the control unit 10 of the vehicle on the receiving side outputs the route change determination result to the monitor 30. As a specific example of the output, for example, an icon indicating the receiving host vehicle that is the subsequent vehicle is displayed next to the icon indicating the other vehicle that is the preceding vehicle, and the icon indicating the host vehicle is displayed near the right side. Displays an icon that instructs to turn left or change lanes. Thereby, based on the result of determining the course change of the other vehicle that is the preceding vehicle, the user of the receiving vehicle can know how the own vehicle that is the succeeding vehicle should change the course in the future.

3 to 6 are diagrams showing examples of displays output on the monitor 30. FIG. (A) of each figure is the display output in step S130, and the operation of the direction indicator of the other vehicle is indicated by an icon displayed on the right shoulder or the left shoulder of the icon C1 indicating the other vehicle. (B) of each figure is the display output in step S160, and the result of determining the course change of the other vehicle is indicated by an icon displayed in the vicinity of the icon C2 indicating the own vehicle. 3 shows the case of a right turn, FIG. 4 shows the case of a lane change to the right, FIG. 5 shows the case of a left turn, and FIG. 6 shows the case of a lane change to the left. However, the display mode on the monitor 30 is not limited to this. For example, the icons C1 and C2 indicating the host vehicle and the other vehicle may be omitted, and the determination result of the operation of the direction indicator and the course change may be simply shown.

In the above description, for example, when the operation information of the direction indicator of the other vehicle is received in step S110, the preparation state for determining the course change of the other vehicle is set. However, the preparation state may be set in other cases. That is, when the acceleration / deceleration amount per fixed time of the other vehicle becomes larger than a certain value, for example, when acceleration / deceleration greater than 20 km / h is performed within a certain time, or the speed of the other vehicle becomes lower than the certain value. In this case, for example, when the speed is lower than 20 km / h, the preparation state may be set.

In addition, even in a preparation state for determining the course change of another vehicle, the maximum value of the change amount of the steering angle is within a certain time (for example, within 1 minute) or before traveling for a certain distance (for example, 100 m). When the value is smaller than a certain value or when the maximum change amount of the angular velocity of the steering angle is smaller than the certain value, the ready state may be canceled.

<1-5. Effects of First Embodiment>
According to the first embodiment described above, the following operational effects can be obtained.

(1) The other vehicle on the transmission side only needs to transmit the travel scene information, and it is not necessary to calculate the recommended route. Therefore, the configuration of the vehicle on the transmission side can be simplified. The receiving-side vehicle that has received the traveling scene information of the other vehicle only needs to determine and output the course change of the other vehicle, and does not need to be displayed on the map, so the configuration of the receiving-side vehicle can be simplified. Can do.

Thus, since the other vehicle and the own vehicle can be known by the own vehicle with the simple configuration of the other vehicle, if the own vehicle is a subsequent vehicle, it can follow the other vehicle that is the preceding vehicle. It becomes easy, and if the host vehicle is a preceding vehicle, it can be easily confirmed whether or not another vehicle that is a succeeding vehicle is following.

(2) According to the present embodiment, since it can be determined whether the other vehicle has made a right or left turn or a lane change, if the receiving vehicle is a succeeding vehicle, it can be easily followed, and the receiving vehicle has advanced. If it is a vehicle, sufficient information for confirming the follow-up of the following vehicle can be obtained.

(3) Since the preparation state is established in a fixed case, data transmission / reception and computer processing in other cases can be minimized, and communication costs and computer processing burdens can be reduced.

(4) When the preparation state is canceled in a fixed case, subsequent data transmission / reception and computer processing can be minimized, and communication costs and computer processing burdens can be reduced.

(5) By making the communication frequency dense in the preparation state, it is possible to quickly and accurately determine the course change of the other vehicle.

(6) An accurate determination can be made by determining the course change of the other vehicle based on the time series change of the direction indicator of the other vehicle and the vehicle speed.

(7) By displaying the determination result as an icon, it can be output by a simple display device. In particular, when the host vehicle is a subsequent vehicle, it is possible to accurately output the traveling scene information of the preceding vehicle and the course that the host vehicle should take in the future. On the other hand, when the host vehicle is a preceding vehicle, if the subsequent vehicle is equipped with the same system, it can be confirmed whether or not the information on the host vehicle is accurately transmitted to the subsequent vehicle.

<1-6. Modification of First Embodiment (FIG. 7)>
FIG. 7 is a flowchart illustrating a processing procedure of the group travel support apparatus according to the modification of the first embodiment. Parts similar to those in FIG. 2 are denoted by the same reference numerals and detailed description thereof is omitted, and differences from the processing in FIG. 2 will be mainly described. In FIG. 2, the course change is determined based on the vehicle speed information and the blinker information of the other vehicle, but in this modification, the course change is determined based on the vehicle speed information and the steering angle information of the other vehicle.

In steps S110 and S120, when the operation information of the direction indicator in the other vehicle is received, it becomes a preparation state for determining the course change of the other vehicle, and in step S130, the information of the direction indicator of the other vehicle is output to the monitor 30. The point that the information is stored in the other vehicle information memory 40 until the information indicating that the operation of the direction indicator in the other vehicle is completed in step S140 is the same as that in FIG.

In the next step S151, the course change determination unit 50 of the receiving vehicle determines the course change of the other vehicle. Specifically, first, based on the winker information, the steering angle information, and the vehicle speed information of the other vehicle stored in the other vehicle information memory 40, the maximum value of the steering angle change amount of the other vehicle during the operation of the direction indicator, and Calculate the maximum amount of change in vehicle speed. For example, the first condition that the maximum value of the change amount of the steering angle while the right direction indicator of the other vehicle is operating is a certain value or more, for example, 30 degrees or more, and the right direction indicator When the second condition that the maximum value of the vehicle speed change amount during operation is a certain value or more, for example, 20 km / h or more is satisfied, it is determined that the vehicle turns to the right. On the other hand, if the maximum value of the change amount of the steering angle during the operation of the right direction indicator is less than 30 degrees and the maximum value of the vehicle speed change amount is less than 20 km / h, it is determined that the lane is changed to the right.

When either one of the first condition and the second condition is not satisfied, it is determined that the vehicle is neither turning left or right nor changing the lane.

In the next step S160, the route change determination result is output to the monitor 30 as in FIG.

<1-7. Effects Specific to Modifications of First Embodiment>
According to this modification, an accurate determination can be made by determining the course change of the other vehicle based on the time-series change of the steering angle of the other vehicle and the time-series change of the vehicle speed.

In particular, when the other vehicle is a preceding vehicle, the preceding vehicle may be hidden behind a building at the corner of the intersection as a result of a right or left turn, or the preceding vehicle may be hidden behind a large vehicle as a result of a lane change. Even if the subsequent communication is interrupted, the course change of the preceding vehicle can be estimated from the time-series change of the steering angle and the time-series change of the vehicle speed before the communication is interrupted.

<2-1. Configuration of Second Embodiment (FIG. 8)>
FIG. 8 is a block diagram showing a configuration example of the group travel support apparatus according to the second embodiment of the present invention. The same parts as those in FIG. 1 of the first embodiment are denoted by the same reference numerals and description thereof is omitted.

In the group travel support device of the second embodiment shown in FIG. 8, in addition to the components of the first embodiment, a GPS receiver 81 and a gyro 82 are connected to the processing unit 110, and the host vehicle positioning unit 80 performs processing. The vehicle information acquisition unit 100 in the unit 110 is provided. These additional configurations are particularly desirable to be provided in the vehicle on the transmission side of the traveling scene information. However, it is most desirable to provide these configurations on both the transmission side and the reception side vehicles. By measuring the position of the vehicle with both vehicles, the relative position between the vehicles can be calculated as will be described later, and by having the same configuration in both vehicles, the traveling scene information can be transmitted and received with each other. This is because each can determine a course change of the opponent's vehicle.

The GPS receiver 81 receives synchronous radio waves from a plurality of GPS satellites, and sends time difference information until receiving the radio waves from the respective GPS satellites to the own vehicle position positioning unit 80.

The gyro 82 detects the direction (traveling direction) of the host vehicle. The detected direction of the host vehicle is sent to the host vehicle position measurement unit 80. Further, the vehicle speed information acquired by the vehicle speed sensor 73 is also sent to the own vehicle position measuring unit 80.

If the GPS receiver 81 has successfully received a radio wave from a GPS satellite, the own vehicle position positioning unit 80 measures the current position of the own vehicle based on the time difference information of the received radio wave. If reception of radio waves from the GPS satellite is not successful, the current position of the vehicle is calculated based on the detection results of the gyro 82 and the vehicle speed sensor 73. The acquired current position information is sent to the control unit 10 as travel scene information.

<2-2. Operation of Second Embodiment (FIG. 9)>
FIG. 9 is a flowchart showing a processing procedure of the group travel support apparatus according to the second embodiment. Parts similar to those in FIG. 2 of the first embodiment may be denoted by the same reference numerals and detailed description thereof may be omitted. Similar to FIG. 2, the flowchart of FIG. 9 also describes processing in the receiving-side vehicle that receives the traveling scene information acquired and transmitted in the other vehicle and determines the course change of the other vehicle. When the direction indicator is actuated in the transmission-side vehicle that is another vehicle, the vehicle information acquisition unit 100 of the transmission-side vehicle, for example, once per second, the vehicle signal such as blinker information, steering angle information, and vehicle speed information. And the traveling scene information including the positional information by the own vehicle position measuring unit 80 is acquired and transmitted to the receiving vehicle via the transceiver 20.

In the following description, the case where the transmitting vehicle as the other vehicle is the preceding vehicle and the receiving vehicle as the own vehicle is the subsequent vehicle will be described, but conversely, the transmitting vehicle as the other vehicle is Even if the receiving vehicle that is the succeeding vehicle or the host vehicle is the preceding vehicle, it is still possible to determine the course change of the other vehicle based on the traveling scene information of the other vehicle and output the result.

First, in step S110, when the receiving vehicle receives the operation information of the direction indicator in the other vehicle by the transmitter / receiver 20, the control unit 10 of the receiving vehicle determines the preparation state for determining the course change of the other vehicle. Become. As specific processing of the ready state, in step S120, storage of other vehicle travel scene information in the other vehicle information memory 40 is started. Furthermore, it is desirable to increase the frequency of communication with the other vehicle in the transmitter / receiver 20 so as to obtain information at a high frequency in preparation for the course change of the other vehicle, and to promptly and accurately determine the course change. Further, when the receiving vehicle includes the own vehicle position measuring unit 80, the GPS receiver 81, etc., it is desirable that the receiving vehicle also starts acquiring its own vehicle position as shown in step S125. .

Further, in step S130, as described with reference to FIGS. 2 and 3 to 6, the control unit 10 of the vehicle on the receiving side outputs the information on the direction indicator received from the other vehicle to the monitor 30.

Next, in step S140, when the information indicating that the operation of the direction indicator in the other vehicle has been completed is received by the transmitter / receiver 20 of the receiving vehicle, the course change determining unit 50 of the receiving vehicle in steps S152 to S154 The course change of the other vehicle is determined. Here, the determination of the course change is a determination as to whether it is a right / left turn or a lane change.

Specifically, when the transmitting vehicle, which is another vehicle, is a preceding vehicle and the receiving vehicle is a succeeding vehicle, first, in step S152, the preceding vehicle at the start of operation of the direction indicator of the preceding vehicle is selected. Based on the position and the position of the following vehicle, the position vector of the preceding vehicle viewed from the following vehicle is calculated. Similarly, the position vector of the preceding vehicle viewed from the succeeding vehicle is calculated based on the position of the preceding vehicle and the position of the succeeding vehicle at the end of the operation of the direction indicator of the preceding vehicle.

Next, based on these position vectors, in step S153, a change in the position vector from the start to the end of the operation of the direction indicator of the preceding vehicle, in particular, a change in the direction of the position vector is calculated. Next, in step S154, if the amount of change in the position vector is equal to or greater than a certain value, for example, 30 degrees or greater, it is determined that the preceding vehicle has turned left or right, and otherwise, it is determined that the lane has been changed. In step S <b> 160, as described with reference to FIG. 2, the control unit 10 of the vehicle on the reception side outputs the determination result of the course change to the monitor 30.

In the above description, for example, when the operation information of the direction indicator of the other vehicle is received in step S110, the preparation state for determining the course change of the other vehicle is entered. Also good. That is, when the acceleration / deceleration amount per fixed time of the other vehicle becomes larger than a certain value, for example, when acceleration / deceleration greater than 20 km / h is performed within a certain time, or the speed of the other vehicle becomes lower than the certain value. In this case, for example, when the speed is lower than 20 km / h, the preparation state may be set.

In addition, even in a preparation state for determining the course change of another vehicle, the maximum value of the change amount of the steering angle is within a certain time (for example, within 1 minute) or before traveling for a certain distance (for example, 100 m). When the value is smaller than a certain value or when the maximum change amount of the angular velocity of the steering angle is smaller than the certain value, the ready state may be canceled.

In the above description, the position of the preceding vehicle is acquired in step S110, the vehicle position on the receiving side is acquired in step S125, and the line segment connecting the own vehicle position and the position of the preceding vehicle is defined as a position vector. However, when the vehicle on the receiving side does not include the own vehicle position measuring unit 80, the GPS receiver 81, etc., it is not necessary to acquire the vehicle position on the receiving side. In this case, instead of the processing in steps S152 to S154, the course change is determined based on the history of the positional information of the transmitting vehicle that is another vehicle. Specifically, the traveling direction of the vehicle on the transmission side is calculated based on the positional information of the multiple points of the preceding vehicle received by the subsequent vehicle immediately after the operation of the direction indicator of the vehicle on the transmission side is started. Similarly, the traveling direction of the vehicle on the transmission side is calculated based on the position information at a plurality of points immediately before the end of the operation of the direction indicator of the vehicle on the transmission side. For example, if the difference between the calculated traveling directions is 30 degrees or more, it is determined that the transmitting vehicle has turned left or right, and if not, it is determined that the lane has been changed. This determination can be made even when the transmitting vehicle, which is another vehicle, is a subsequent vehicle and the receiving vehicle is a preceding vehicle.

Further, in the above description, the monitor 30 displays the information on the direction indicator operated on the other vehicle and the information on whether the other vehicle has turned left or right or changed lanes. You may output to the monitor 30 grade | etc., The position which the vehicle changed the course or the position which actuated the direction indicator.

In order to display the position, for example, it is only necessary to display relative position information such as how many meters ahead or how many meters behind the host vehicle, and it is not necessary to display a map.

<2-3. Effect of Second Embodiment>
According to the second embodiment described above, similar to the first embodiment, the course change of the other vehicle can be known by the own vehicle with a simple configuration for both the other vehicle and the own vehicle. Therefore, if the host vehicle is a subsequent vehicle, it is easy to follow the other vehicle that is the preceding vehicle. If the host vehicle is the preceding vehicle, whether or not the other vehicle that is the succeeding vehicle is following. Can be easily confirmed.

Although the second embodiment deals with vehicle position information, it is not necessary to display the position of the vehicle on a map, so that a simple configuration can be realized as in the first embodiment. Furthermore, since it is possible to determine the course change only by calculating the change of the vehicle position vector or the traveling direction, it is not necessary to refer to the map data as in the first embodiment, and it is not necessary to have enormous map data.

<3-1. Configuration of Third Embodiment (FIG. 10)>
FIG. 10 is a block diagram illustrating a configuration example of the group travel support apparatus according to the third embodiment of the present invention. The same parts as those in FIG. 1 of the first embodiment are denoted by the same reference numerals and description thereof is omitted.

In the group travel support device of the third embodiment shown in FIG. 10, in addition to the components of the first embodiment, a GPS receiver 81 and a gyro 82 are connected to the processing unit 110, and the own vehicle position positioning unit 80 performs processing. The vehicle information acquisition unit 100 in the unit 110 is provided. Further, a road map memory 91 is connected to the processing unit 110, and a road information acquisition unit 90 is provided in the vehicle information acquisition unit 100 in the processing unit 110.

Among these additional configurations, it is desirable that the GPS receiver 81, the gyro 82, and the vehicle position measuring unit 80 are particularly provided in the vehicle on the transmission side of the traveling scene information. The road map memory 91 and the road information acquisition unit 90 are preferably provided in at least one of the transmission-side vehicle and the reception-side vehicle. However, it is most desirable to provide these configurations on both the transmission side and the reception side vehicles. This is because by providing the same configuration in both the vehicles, the traveling scene information can be transmitted and received, and each can determine the course change of the opponent vehicle.

The GPS receiver 81 receives synchronous radio waves from a plurality of GPS satellites, and sends time difference information until receiving the radio waves from the respective GPS satellites to the own vehicle position positioning unit 80.

The gyro 82 detects the direction (traveling direction) of the host vehicle. The detected direction of the host vehicle is sent to the host vehicle position measurement unit 80. Further, the vehicle speed information acquired by the vehicle speed sensor 73 is also sent to the own vehicle position measuring unit 80.

If the GPS receiver 81 has successfully received a radio wave from a GPS satellite, the own vehicle position positioning unit 80 measures the current position of the own vehicle based on the time difference information of the received radio wave. If reception of radio waves from the GPS satellite is not successful, the current position of the vehicle is calculated based on the detection results of the gyro 82 and the vehicle speed sensor 73. The acquired current position information is sent to the control unit 10 as travel scene information.

The road map memory 91 stores road shape information, intersection connection information, road type information, lane information, and the like. The road shape information is information expressed by road links and nodes, and includes the position coordinates of the nodes. The intersection connection information is information on links and nodes connected to the intersection. The road type information includes information on whether each road is an expressway or a motorway, a national road, a prefectural road, a municipal road, and information on the presence or absence of an intersection at each position. Here, the intersection includes a three-way road such as a T-shaped road and a Y-shaped road, a four-way road such as a cross road, or a road having five or more roads. The lane information is information on the precise position of each road and the lane provided on the road.

The road information acquisition unit 90 accesses the road type information in the road map memory 91, acquires road type information at a certain vehicle position, and sends it to the control unit 10 as travel scene information. Alternatively, lane information in the road map memory 91 is accessed, lane information at a certain vehicle position is acquired, and which lane of which road is traveling is sent to the control unit 10 as traveling scene information.

<3-2. Operation of Third Embodiment (FIG. 11)>
FIG. 11 is a flowchart illustrating a processing procedure of the group travel support apparatus according to the third embodiment. Parts similar to those in FIG. 2 of the first embodiment may be denoted by the same reference numerals and detailed description thereof may be omitted. Similarly to FIG. 2, the flowchart of FIG. 11 also describes processing in the receiving-side vehicle that receives the traveling scene information acquired and transmitted in the other vehicle and determines the course change of the other vehicle.

When the direction indicator is actuated in the transmission-side vehicle that is another vehicle, the vehicle information acquisition unit 100 of the transmission-side vehicle, for example, once per second, the vehicle signal such as blinker information, steering angle information, and vehicle speed information. And the traveling scene information including the positional information by the own vehicle position measuring unit 80 is acquired and transmitted to the receiving vehicle via the transceiver 20. In addition, when the transmission side vehicle which is another vehicle is provided with the road map memory 91 and the road information acquisition part 90, it replaces with the positional information by the own vehicle position-positioning part 80, or with this, the road information acquisition part 90 The road information may be transmitted to the receiving vehicle.

In the following description, the case where the transmitting vehicle as the other vehicle is the preceding vehicle and the receiving vehicle as the own vehicle is the subsequent vehicle will be described, but conversely, the transmitting vehicle as the other vehicle is Even if the receiving vehicle that is the succeeding vehicle or the host vehicle is the preceding vehicle, it is still possible to determine the course change of the other vehicle based on the traveling scene information of the other vehicle and output the result.

First, in step S110, when the receiving vehicle receives the operation information of the direction indicator in the other vehicle by the transmitter / receiver 20, the control unit 10 of the receiving vehicle determines the preparation state for determining the course change of the other vehicle. Become. As specific processing of the ready state, in step S120, storage of other vehicle travel scene information in the other vehicle information memory 40 is started. Furthermore, it is desirable to increase the frequency of communication with the other vehicle in the transmitter / receiver 20 so as to obtain information at a high frequency in preparation for the course change of the other vehicle, and to promptly and accurately determine the course change.

Further, in step S130, as described with reference to FIGS. 2 and 3 to 6, the control unit 10 of the vehicle on the receiving side outputs the information on the direction indicator received from the other vehicle to the monitor 30.

Next, in steps S155 and S156, the course change determination unit 50 of the receiving vehicle determines the course change of the other vehicle. Here, the determination of the course change is a determination as to whether it is a right / left turn or a lane change.

Specifically, first, in step S155, the road type information of the road on which the transmitting vehicle is traveling is acquired from the traveling scene information of the transmitting vehicle stored in the other vehicle information memory 40. In particular, when the road type information is not transmitted from the transmission side vehicle, the road information acquisition unit 90 of the reception side vehicle accesses the road map memory 91 based on the vehicle position of the transmission side vehicle. The road type information of the vehicle is acquired.

Next, in step S156, the course change is determined as follows based on the type of road and the presence or absence of an intersection in the vicinity thereof. In other words, if the road on which the transmitting vehicle is traveling is an expressway or an automobile-only road, there is no branch unless there is a parking area, service area, junction, etc., so the direction indicator operates on the transmitting vehicle. If so, it is determined that the lane has been changed. However, there is a possibility that the vehicle has stopped on the shoulder due to a failure, etc. In that case, the hazard or left direction indicator has been operating for a long time, so if the direction indicator has operated for, for example, 30 seconds or more, the lane has changed. It is determined that the vehicle is stopped. On the other hand, if the road on which the transmitting vehicle is traveling is a road other than an expressway or an automobile-only road, the presence / absence of a nearby intersection is determined. For example, when there is an intersection within 50 m ahead of the transmission-side vehicle, it is determined that the turn signal is operating, and it is determined that the vehicle is turning right and left, and when there is no intersection, it is determined that the lane is changed.

Next, in step S <b> 160, as described with reference to FIG. 2, the control unit 10 of the vehicle on the receiving side outputs the determination result of the course change to the monitor 30.

In the above description, for example, when the operation information of the direction indicator of the other vehicle is received in step S110, the preparation state for determining the course change of the other vehicle is entered. Also good. That is, when the acceleration / deceleration amount per fixed time of the other vehicle becomes larger than a certain value, for example, when acceleration / deceleration greater than 20 km / h is performed within a certain time, or the speed of the other vehicle becomes lower than the certain value. In this case, for example, when the speed is lower than 20 km / h, the preparation state may be set.

In addition, even in a preparation state for determining the course change of another vehicle, the maximum value of the change amount of the steering angle is within a certain time (for example, within 1 minute) or before traveling for a certain distance (for example, 100 m). When the value is smaller than a certain value or when the maximum change amount of the angular velocity of the steering angle is smaller than the certain value, the ready state may be canceled.

<3-3. Effect of Third Embodiment>
According to the third embodiment described above, similar to the first embodiment, the course change of the other vehicle can be known by the own vehicle with a simple configuration for both the other vehicle and the own vehicle. Therefore, if the host vehicle is a subsequent vehicle, it is easy to follow the other vehicle that is the preceding vehicle. If the host vehicle is the preceding vehicle, whether or not the other vehicle that is the succeeding vehicle is following. Can be easily confirmed.

Although the third embodiment deals with vehicle position information, it is not necessary to display the position of the vehicle on a map, so that a simple configuration can be realized as in the first embodiment.

Further, according to the third embodiment, since the course change of the other vehicle is determined based on the road information of the road on which the other vehicle is traveling, more accurate determination can be performed.

Moreover, since the presence or absence of an intersection is known from the road type information, it is possible to accurately determine the course change of another vehicle.

<3-4. Modification of Third Embodiment (FIG. 12)>
FIG. 12 is a flowchart illustrating a processing procedure of the group travel support apparatus according to the modification of the third embodiment. Portions similar to those in FIG. 11 are denoted by the same reference numerals, detailed description thereof is omitted, and differences from the processing in FIG. 11 are mainly described. In FIG. 11, the route change is determined using road type information as road information of other vehicles, but in this modification, the route change is determined using lane information as road information of other vehicles.

In Steps S110 and S120, when the operation information of the direction indicator in the other vehicle is received, it becomes a preparation state for determining the course change of the other vehicle, and the information is stored in the other vehicle information memory 40. In Step S130, the information of the other vehicle is stored. The point indicator information is output to the monitor 30 as in FIG.

Next, in steps S157 and S158, the course change determination unit 50 of the receiving vehicle determines the course change of the other vehicle. Here, the determination of the course change is a determination as to whether it is a right / left turn or a lane change.

Specifically, first, in step S157, lane information in which the transmitting vehicle is traveling is acquired from the traveling scene information of the transmitting vehicle stored in the other vehicle information memory 40. In particular, when the lane information is not transmitted from the transmitting vehicle, the road information acquisition unit 90 of the receiving vehicle accesses the road map memory 91 based on the vehicle position of the transmitting vehicle, and Get vehicle lane information.

Next, in step S158, the route change is determined as follows based on information on which lane of which road the transmission-side vehicle is running. That is, when the transmitting vehicle moves to another lane on the same road, it is determined as a lane change. When moving from one road to another, it is determined that the turn is right or left. If the road and the lane do not change within a certain time after the start of the operation of the direction indicator, it may be determined that the vehicle is going straight.

In the next step S160, the route change determination result is output to the monitor 30 as in FIG.

<3-5. Effects Specific to Modifications of Third Embodiment>
According to this modification, it is possible to directly determine the course change of the other vehicle based on the lane information of the other vehicle, and thus it is possible to accurately determine the course change.

<4. Explanation of terms>
The transmitter / receiver 20 in each of the embodiments described above is the “transmission / reception means” of the present invention, the route change determination unit 50 is the “route change determination means”, and the monitor 30 is the “determination result output means”. The positioning unit 80 corresponds to “position information acquisition means”. The scene travel information acquired by the vehicle information acquisition unit 100 corresponds to “travel status information”.

Note that the first to third embodiments described above can be configured not only by themselves but also by any combination thereof. For example, by combining the first embodiment and the second embodiment, the course change can be determined by adding the determination result based on the position information to the determination result based on the vehicle signal such as the direction indicator and the vehicle speed. Further, for example, by combining the first or second embodiment or the combination thereof with the third embodiment, it is possible to determine the course change by further adding the determination result based on the road information.

20: Transmitter / receiver
100 ... Vehicle information acquisition unit 50 ... Course change determination unit
30 ... monitor 80 ... own vehicle position measurement part
C1 ... Icon indicating the preceding vehicle C2 ... Icon indicating the following vehicle

Claims (5)

A transmission / reception means for transmitting / receiving information representing the driving status of the vehicle (hereinafter referred to as driving status information);
A course change determination means for judging a course change of a vehicle (hereinafter referred to as a transmission station vehicle) that has transmitted the traveling situation information based on the traveling situation information received by the transmission / reception means;
Determination result presenting means for presenting the determination result by the course change determining means to the occupant;
With
The traveling state information includes information on a direction indicator of the transmitting station vehicle, information on a steering angle of the transmitting station vehicle, or information on the transmitting station vehicle with respect to a vehicle that receives the traveling state information (hereinafter referred to as a receiving station vehicle). Including at least one piece of relative position information and position information;
The route change determination means acquires the road type information of the transmission station vehicle based on the position information of the transmission station vehicle received by the transmission / reception means and the road type information of the reception station vehicle,
Information on the direction indicator of the transmitting station vehicle, information on the steering angle of the transmitting station vehicle, or information on the relative position of the transmitting station vehicle with respect to the receiving station vehicle, and the transmitting station vehicle A group travel support apparatus for determining a route change of the transmission station vehicle based on a road type of the vehicle. A transmission / reception means for transmitting / receiving information representing the driving status of the vehicle (hereinafter referred to as driving status information);
A course change determination means for judging a course change of a vehicle (hereinafter referred to as a transmission station vehicle) that has transmitted the traveling situation information based on the traveling situation information received by the transmission / reception means;
Determination result presenting means for presenting the determination result by the course change determining means to the occupant;
With
The travel status information includes position information,
The route change determination means is based on position information of the transmission station vehicle received by the transmission / reception means and lane information of a vehicle that receives the position information (hereinafter referred to as reception station vehicle). Lane information
From the lane information that the transmitting station vehicle is traveling and the lane information that the receiving station vehicle is traveling, whether the transmitting station vehicle is traveling on the same road as the receiving station vehicle, and the same road as the receiving station vehicle And determining which lane the vehicle is traveling in, thereby determining a course change of the transmitting station vehicle. In the group driving assistance device according to claim 1 or 2,
The traveling state information includes vehicle speed information,
The course change determination means is
Based on the vehicle speed information received by the transmitting / receiving means, when the acceleration / deceleration amount of the transmission station vehicle is greater than a certain value, or when the speed of the transmission station vehicle is less than a certain value,
The group travel support apparatus, which shifts to a preparation state for determining a course change of the transmission station vehicle. In the group driving assistance device according to claim 1 or 2,
The traveling state information includes steering angle information,
The course change determination means is
The maximum value of the change amount of the steering angle of the transmission station vehicle is less than a predetermined value within a predetermined time period or after traveling to a predetermined distance after transitioning to a preparation state for determining a course change of the transmission station vehicle, The group driving support device, wherein the preparation state is canceled when the maximum value of the change amount of the angular velocity of the steering angle of the transmitting station vehicle is smaller than a certain value. In the group driving assistance device according to claim 1 or 2,
The transmission / reception means increases the communication frequency of the traveling status information when shifting to a preparation state for determining a course change of the transmitting station vehicle as compared to before shifting.

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