The present disclosure relates to a platooning system.
Patent Document 1 describes a typical example of a technique for causing vehicles to platoon through the execution of an inter-vehicle distance control by means of vehicle-to-vehicle communication in the vehicles.
The head vehicle of a platoon may be driven manually by a driver. The manually-driven head vehicle and its subsequent unmanned vehicle coordinate with each other through vehicle-to-vehicle communication so that the vehicles platoon.
Patent Document 1: Japanese Laid-Open Patent Publication No. 2012-30666
When the head vehicle of a platoon is manually driven, the driver of the head vehicle needs to operate the platoon while grasping the situation of the subsequent vehicle. However, the driver of the head vehicle may be unable to fully grasp the situation of the subsequent vehicle. Thus, for example, when an anomaly occurs in the subsequent vehicle, the driver of the head vehicle may continue to operate the platoon without noticing the anomaly in the subsequent vehicle.
It is an objective of the present disclosure to provide a platooning system capable of properly transmitting, to a manually-driven head vehicle, the state of its subsequent vehicle.
A platooning system that can solve the above-described objective includes a vehicle control system installed in each of the vehicles that include a manually-driven head vehicle. The vehicle control system is configured to control a host vehicle such that the host vehicle follows a lead vehicle through wireless communication between the host vehicle and the lead vehicle. The vehicle control system is installed in the host vehicle and the lead vehicle. The vehicle control system includes a sensor configured to detect a state of the host vehicle, an actuator configured to adjust a behavior of the host vehicle, and a controller configured to control the host vehicle. The controller of the head vehicle is configured to physically notify a driver of the host vehicle of a state of a subsequent vehicle by operating the actuator of the host vehicle when a state signal including information that indicates the state of the subsequent vehicle is received through the wireless communication.
A platooning system according to an embodiment will now be described.
As shown in
As shown in
The front monitoring sensor 21 is provided at the front of a vehicle to monitor the front of the host vehicle and detect the distance between the host vehicle and a vehicle that is traveling right in front of the host vehicle. The rear monitoring sensor 22 is provided at the rear of a vehicle to monitor the rear of the host vehicle and detect the distance between the host vehicle and a vehicle that is traveling right behind the host vehicle. The side monitoring sensor 23 is provided at the side of a vehicle to monitor the side of the host vehicle and detect the distance between the host vehicle and a vehicle that is traveling beside the host vehicle. Examples of these monitoring sensors 21, 22, and 23 include a radar, such as a laser radar or a millimeter wave radar, and a camera.
The vehicle speed sensor 24 detects the traveling speed of the host vehicle. The acceleration sensor 25 detects the acceleration of the host vehicle in the front-rear direction. The GPS receiver 26 receives a position measurement signal from an artificial satellite for a global positioning system (GPS) and uses the received position measurement signal to detect the position (latitude and longitude) of the host vehicle and the azimuth of the host vehicle. The vehicle-to-vehicle communication device 27 executes wireless communication between vehicles. The anomaly detection sensor 28 detects an anomaly in each part of the host vehicle.
The throttle actuator 31 regulates the amount of fuel supplied to the engine by regulating a throttle open degree. The brake actuator 32 regulates a braking force to decelerate the vehicle via a brake device. The steering actuator 33 steers the right and left wheels by moving a steering rod in the axial direction. The suspension actuator 34 changes the vehicle height by driving, for example, an air suspension. The speaker 35 produces a sound. The display device 36 displays various information. The display device 36 includes various warning lights and a display.
The ECU 20 centrally controls the entire vehicle. The ECU 20 may be processing circuitry including: 1) one or more processors that execute various processes according to a computer program (software); 2) one or more dedicated hardware circuits (ASICs) that execute at least part of the various processes, or 3) a combination thereof. The processor includes a CPU and memories such as a RAM and a ROM. The memories store program codes or commands configured to cause the CPU to execute processes. The memories, or computer readable media, include any type of media that are accessible by general-purpose computers and dedicated computers.
The ECU 20 controls an output of the engine via the throttle actuator 31. The ECU 20 increases the amount of fuel supplied to the engine via the throttle actuator 31 when accelerating the vehicle and decreases the amount of fuel supplied to the engine via the throttle actuator 31 when decelerating the vehicle. Also, the ECU 20 controls the braking force of the vehicle via the brake actuator 32. The ECU 20 controls the speed and inter-vehicle distance of the vehicle via the throttle actuator 31 and the brake actuator 32. Further, the ECU 20 controls the steerable angle of a wheel via the steering actuator 33. Furthermore, the ECU 20 controls the vehicle height via the suspension actuator 34.
The ECU 20 of each vehicle sends and receives information, such as vehicle traveling data and identification information (ID), to and from other vehicles via the vehicle-to-vehicle communication device 27. The traveling data is information related to the traveling state of the host vehicle. For example, the traveling data includes information such as the position, speed, acceleration, and azimuth (advancement direction) of the host vehicle. The identification information includes vehicle identification information, which is unique to the host vehicle, and platoon identification information, which is unique to a platoon to which the host vehicle belongs.
The ECU 20 executes adaptive cruise control (ACC). ACC measures the distance between the host vehicle and its preceding lead vehicle via the front monitoring sensor 21 and causes the host vehicle to travel in accordance with the acceleration/deceleration and stopping of the front vehicle while maintaining a preset inter-vehicle distance and speed. The preceding lead vehicle includes a general vehicle that does not belong to a platoon. In ACC, a difference between the lead vehicle and the host vehicle in the width direction is detected by the front monitoring sensor 21, and the steering of the host vehicle is controlled so as to eliminate the detected difference.
For example, the ECU 20 executes a traveling control for a vehicle such that the vehicle travels with a set vehicle speed maintained when its lead vehicle is not detected during the execution of ACC. Further, when a lead vehicle that travels at a speed lower than the set vehicle speed is detected, the ECU 20 executes a following control such that the distance from the lead vehicle remains a preset inter-vehicle distance. The ECU 20 controls the acceleration of a vehicle such that the distance from its lead vehicle does not become smaller than the preset inter-vehicle distance. That is, when the vehicle speed of the lead vehicle is lower than the set vehicle speed, the ECU 20 lowers the vehicle speed of the host vehicle to maintain the inter-vehicle distance.
The ECU 20 executes cooperative adaptive cruise (CACC). CACC causes vehicles laid out in the same lane to platoon by coordinating the vehicles through wireless communication. In platooning, vehicles equipped with the vehicle control systems 11 travel in single file so as to form a platoon while maintaining a certain inter-vehicle distance and a certain speed in a state where a general vehicle is not located between the vehicles in the same lane.
In CACC, the acceleration of the host vehicle is controlled based on the information related to another vehicle in the platoon acquired through vehicle-to-vehicle communication. This causes the host vehicle to follow the preceding vehicle in the platoon such that the distance between the host vehicle and the preceding vehicle remains a target inter-vehicle distance. The platoon-forming vehicles CS1 to CS3 mutually send and receive information such as the specification and traveling data of the host vehicle via the vehicle-to-vehicle communication device 27. That is, the vehicle control systems 11 of all the platoon-forming vehicles CS1 to CS3 share information, such as the specifications and traveling data of all the platoon-forming vehicles CS1 to CS3.
For example, when the brake device is activated in the head vehicle of a platoon, the information indicating the activation is transmitted to all the vehicles in the platoon. All the vehicles forming the platoon automatically decelerate at a proper timing while maintaining the inter-vehicle distances. When the head vehicle accelerates, the accelerating degree of the head vehicle is transmitted to all the vehicles in the platoon. All the vehicles forming the platoon automatically accelerate in order to maintain the inter-vehicle distances and speeds in the entire platoon.
The operation of the platooning system will now be described. As shown in
Each of the vehicles CS2 and CS3 other than the head vehicle CS1 of the platoon may follow its preceding vehicle based on the traveling state of the preceding vehicle. In this case, the traveling state of the second vehicle CS2 of the platoon is controlled based on the traveling state of the head vehicle CS1. The traveling state of the third vehicle CS3 of the platoon is controlled based on the traveling state of the preceding vehicle CS2.
When the head vehicle CS1 of the platoon is driven manually by a driver, the following problem may occur. That is, when the head vehicle CS1 is manually driven, the driver of the vehicle CS1 needs to operate the platoon while grasping the situations of the subsequent vehicles CS2 and CS3. However, the driver of the head vehicle CS1 may be unable to fully grasp the situations of the subsequent vehicles CS2 and CS3. This becomes more noticeable as the number of platoon-forming vehicles increases.
To solve this problem, the platooning system 10 transmits the states of the subsequent vehicles CS2 and CS3 to the head vehicle CS1 as follows.
For example, when an anomaly occurs in a subsequent vehicle, the anomaly is detected by the anomaly detection sensor 28 of the subsequent vehicle. The ECU 20 of the subsequent vehicle wirelessly transmits a state signal Sw, which indicates that an anomaly has occurred in the host vehicle, via the vehicle-to-vehicle communication device 27. Examples of the state signal Sw include the information indicating the contents of an anomaly, a section where an anomaly has occurred, and the identification information of a vehicle where an anomaly has occurred.
Examples of the anomaly detected by the anomaly detection sensor 28 include:
(a1) Anomaly in engine;
(a2) Anomaly in steering device;
(a3) Anomaly in brake device;
(a4) Anomaly in tire; and
(a5) Anomaly in vehicle behavior.
When the state signal Sw is received through vehicle-to-vehicle communication, the ECU 20 of the head vehicle uses the information included in the state signal Sw to grasp the subsequent vehicle where the anomaly has occurred and grasp the contents of the anomaly. Further, the ECU 20 of the head vehicle executes at least one of a first physical notification control and a second physical notification control in order to physically notify the driver of the head vehicle of the anomaly in the subsequent vehicle.
The first physical notification control causes the same anomalous state as that of the subsequent vehicle to occur in the head vehicle in a simulated manner via the various actuators of the head vehicle. The first physical notification control causes the driver of the head vehicle to virtually experience the same anomalous state as that of the subsequent vehicle. This further ensures the transmission of the anomaly in the subsequent vehicle.
However, depending on the contents or degree of an anomaly that has occurred in the subsequent vehicle, it is preferred that the degree of the anomalous state generated in the head vehicle in a simulated manner be limited to a degree that does not hamper driving.
Specific examples of the first physical notification control are as follows.
(b1) Anomaly in engine of subsequent vehicle (e.g., output decrease)
In this case, the ECU 20 of the head vehicle limits an engine output via the throttle actuator 31 to generate the state of the subsequent vehicle in a simulated manner. The driver of the head vehicle virtually experiences the vehicle behavior of the subsequent vehicle where an anomaly has occurred in the engine. This allows the driver to notice the anomaly in the subsequent vehicle.
(b2) Flat tire on one side in subsequent vehicle
In this case, the ECU 20 of the head vehicle gives torque to the steering wheel via the steering actuator 33 to generate, in a simulated manner, a steering feel that occurs when the subsequent vehicle has a flat tire on one side. The driver of the head vehicle virtually experiences the vehicle behavior of the subsequent vehicle that has had a flat tire on one side. This allows the driver to notice the anomaly in the subsequent vehicle.
(b3) Impact in subsequent vehicle
In this case, the ECU 20 of the head vehicle generates, in a simulated manner via the brake actuator 32, the suspension actuator 34, and the like, an impact that has occurred in the subsequent vehicle. The driver of the head vehicle virtually experiences the impact that has occurred in the subsequent vehicle. This allows the driver to notice the anomaly in the subsequent vehicle.
(b4) Anomaly in vehicle behavior in subsequent vehicle (e.g., such as sudden acceleration change)
In this case, the ECU 20 of the head vehicle generates, in a simulated manner via the brake actuator 32, a change in the acceleration that has occurred in the subsequent vehicle. The driver of the head vehicle virtually experiences the change in the acceleration that has occurred in the subsequent vehicle. This allows the driver to notice the anomaly in the subsequent vehicle.
The second physical notification control physically notifies the driver of the lead vehicle of a section of the subsequent vehicle where an anomaly has occurred.
Specific examples of the second physical notification control are as follows.
(c1) Anomaly in section of subsequent vehicle causing vehicle to travel (e.g., engine)
In this case, the ECU 20 of the head vehicle vibrates the accelerator pedal via the throttle actuator 31. The driver of the head vehicle feels the accelerator pedal vibrating. This allows the driver to notice that the anomaly has occurred in, for example, the engine of the subsequent vehicle.
(c2) Anomaly in section of subsequent vehicle changing vehicle advancement direction (e.g., steering device)
In this case, the ECU 20 of the head vehicle vibrates the steering wheel via the steering actuator 33. The driver of the head vehicle feels the steering wheel vibrating. This allows the driver to notice that the anomaly has occurred in, for example, the steering device of the subsequent vehicle.
(c3) Anomaly in vehicle-braking section of subsequent vehicle (e.g., brake device)
In this case, the ECU 20 of the head vehicle vibrates the brake pedal via the brake actuator 32. The driver of the head vehicle feels the brake pedal vibrating. This allows the driver to notice that the anomaly has occurred in, for example, the brake device of the subsequent vehicle.
(c4) Anomaly in chassis of subsequent vehicle (e.g., flat tire)
In this case, the ECU 20 of the head vehicle vibrates the suspension via the suspension actuator 34. The driver of the head vehicle feels the suspension vibrating. This allows the driver to notice that the anomaly has occurred in, for example, the chassis of the subsequent vehicle.
Additionally, when an anomaly is detected in the subsequent vehicle, the ECU 20 of the head vehicle may execute control to ensure the safety of the platoon operation or the road traffic safety around the platoon.
For example, the ECU 20 of the head vehicle sets an upper limit speed for the operation speed of the entire platoon in correspondence with the contents of an anomaly that has occurred in the subsequent vehicle. As another option, in order for the entire platoon to decelerate, the ECU 20 of the head vehicle may cause the head vehicle to travel at a speed lower than the operation speed prior to the detection of an anomaly in the subsequent vehicle. As an alternative, depending on the contents or degree of an anomaly that has occurred in the subsequent vehicle, the ECU 20 of the head vehicle may execute an automatic evacuation control. By executing the automatic evacuation control, the ECU 20 of the head vehicle coordinates with the subsequent vehicle through vehicle-to-vehicle communication to move the platoon to a safety place, such as a shoulder, regardless of the driving state of the driver of the host vehicle.
Accordingly, the present embodiment provides the following advantages.
(1) The platooning system 10 physically notifies the driver of the head vehicle of an anomaly in the subsequent vehicle. This allows the anomaly in the subsequent vehicle to be properly transmitted to the driver of the head vehicle.
(2) An anomaly in the subsequent vehicle is immediately transmitted to the head vehicle through vehicle-to-vehicle communication. This allows the driver of the head vehicle to quickly deal with an anomaly that has occurred in the subsequent vehicle. For example, the driver of the head vehicle is capable of quickly decelerating or stopping the host vehicle. This ensures safer operation of a platoon and also contributes to the road traffic safety around the platoon.
(3) The ECU 20 of the head vehicle of a platoon uses the information, included in the state signal Sw, indicating an anomaly that has occurred in the subsequent vehicle to coordinate with the subsequent vehicle through vehicle-to-vehicle communication, thereby limiting the operation of the entire platoon. This ensures the safety of the platoon operation or the road traffic safety around the platoon.
The present embodiment may be modified as follows.
When an anomaly has been detected in a subsequent vehicle, in addition to physically notifying the driver of the host vehicle of the state of the subsequent vehicle, the ECU 20 of the head vehicle may appeal to the visual or hearing sense of the driver of the host vehicle to notify the driver of the host vehicle of the anomaly in the subsequent vehicle. For example, the ECU 20 of the head vehicle produces a warning sound via the speaker 35 of the host vehicle or causes the display device 36 to display a warning.
When an anomaly has been detected in a subsequent vehicle, the ECU 20 of the head vehicle does not have to generate, in a simulated manner, the same anomalous state as the anomaly that has occurred in the subsequent vehicle. For example, the ECU 20 of the head vehicle may vibrate a section unrelated to a section of the subsequent vehicle where the anomaly has occurred, such as a seat, to notify the driver of the host vehicle of the anomaly in the subsequent vehicle. At least the driver of the head vehicle needs to notice that an anomaly has occurred in the subsequent vehicle by a bodily feeling.
The ECU 20 of the head vehicle may physically notify the driver of the head vehicle not only of an anomaly that has occurred in a subsequent vehicle but also of the state of the subsequent vehicle in which the anomaly has not occurred. For example, the ECU 20 of the head vehicle may generate a state change, such as the degree of deceleration of the subsequent vehicle or an increase in the traveling resistance, in a simulated manner via the brake actuator 32. This allows the driver of the head vehicle to operate the platoon while constantly grasping the state of the subsequent vehicle.
Number | Date | Country | Kind |
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2018-084287 | Apr 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/016933 | 4/22/2019 | WO | 00 |