JP5919150B2 - Driving assistance device - Google Patents

Description

  The present invention relates to a driving support device that supports driving when a driver falls into a difficult driving state.

  In recent years, various techniques for supporting driving of a vehicle by a driver have been developed. For example, follow-up control that automatically travels while maintaining a certain distance from the preceding vehicle ahead, technology to notify the driver of the presence of an obstacle when there is an obstacle ahead, and avoid collision with the obstacle There is a collision avoidance technology that automatically brakes and stops. These are assistive technologies aimed at reducing the driving burden on the driver.

  On the other hand, a technology called an emergency evacuation system has been developed to evacuate the host vehicle to a safe place in order to ensure the safety of the host vehicle, other vehicles, pedestrians, etc. when the driver falls into a difficult driving situation. . For example, in the system described in Patent Document 1, when it is determined that the driver is in a coma, the vehicle is automatically retracted to the road shoulder and stopped. Specifically, when it is determined that the driver is in a coma during the lane change, it is determined whether the travel lane after crossing is farther from the vehicle lane with respect to the shoulder of the evacuation destination, The presence or absence of a rear vehicle is considered. When the driving lane after crossing is farther than the host vehicle lane, if the rear vehicle is not detected, the vehicle can be returned to the original driving lane to reduce the number of lane changes when retreating to the road shoulder. It is said that.

JP 2009-151522 A

  However, in the system of Patent Document 1 described above, when it is determined that the driver is in a coma, the vehicle is automatically retracted to the road shoulder, but the road shoulder as the retreat destination is always a safe place. Is not limited. For example, it is difficult to say that the vehicle is safe when another vehicle is stopped on the shoulder or a pedestrian is present. In addition, in the case of a road where there is no road shoulder, the evacuation destination may not be found immediately. In addition, when it is determined that the driver is in a difficult driving state and deceleration is automatically started, the following vehicle may collide.

This case has been devised in view of such problems, and it is intended to provide a driving assistance device that can reduce secondary damage when the driver is in a difficult driving state. Objective.
The present invention is not limited to this purpose, and is a function and effect derived from each configuration shown in the embodiments for carrying out the invention described later, and other effects of the present invention are to obtain a function and effect that cannot be obtained by conventional techniques. Can be positioned.

(1) The driving support apparatus disclosed herein includes a state determination unit that determines a state of a driver that drives the host vehicle, and an information acquisition unit that acquires peripheral information including information on a preceding vehicle traveling in front of the host vehicle. Vehicle control means for performing tracking control including vehicle speed control and steering angle control so that the host vehicle travels following the preceding vehicle. The vehicle control means automatically starts the follow-up control for the preceding vehicle based on the peripheral information acquired by the information acquisition means when the state determination means determines that the driver is abnormal. and, if said information the preceding vehicle stop information by the acquisition means during the implementation of the following control is obtained the stops the vehicle to exit the follow-up control, the vehicle as the preceding vehicle started to run again When the preceding vehicle for carrying out the follow-up control does not exist, the standby control for automatically running at a reduced speed to the extent that no rear-end collision is made based on the surrounding information is performed. It is a feature.

The state determination means determines whether or not there is an abnormality in the state (health state) of the driver. The “abnormality” here means a state where it is difficult to drive the vehicle or a state where it cannot be driven at all, such as when the driver falls into a heartbeat stop, death, or deep sleep (coma state).
The information acquisition means includes information on the preceding vehicle (position information, speed information, etc.), information on a subsequent vehicle that travels behind the host vehicle (position information, speed information, etc.), white line information, signal information, etc. Get road information.

  In addition to vehicle speed control for controlling the vehicle speed of the host vehicle and steering angle control for controlling the steering angle, the vehicle control means, for example, an inter-vehicle distance control for controlling an inter-vehicle distance so as to maintain a constant distance from the preceding vehicle, etc. May be included. Further, the vehicle control means stops the own vehicle once the preceding vehicle stops, and does not follow the end of the following control even if the preceding vehicle starts running again (that is, the own vehicle is stopped). Continue).

  (2) The preceding vehicle includes a first preceding vehicle that travels in the same lane as the host vehicle and a second preceding vehicle that travels in an adjacent lane adjacent to the lane, and the vehicle control means When it is determined by the determination means that the driver is abnormal, when the information acquisition means acquires both the information on the first preceding vehicle and the second preceding vehicle, it is automatically applied to the first preceding vehicle. In particular, it is preferable to implement the follow-up control.

  In other words, when it is determined that the driver is abnormal while traveling on a road with two or more lanes on one side, the first preceding vehicle traveling in the same lane as the host vehicle and the adjacent lane adjacent to the lane When information indicating that there is a second preceding vehicle is acquired, it is preferable to prioritize the first preceding vehicle and automatically perform the follow-up control on the first preceding vehicle. Furthermore, when there are a plurality of the first preceding vehicles, it is more preferable to give priority to the nearest first preceding vehicle.

  (3) Furthermore, the vehicle control means, when it is determined by the state determination means that the driver is abnormal, when only the information on the second preceding vehicle is acquired by the information acquisition means, It is determined whether or not there is an adjacent succeeding vehicle traveling behind the host vehicle in the adjacent lane on which the second preceding vehicle travels, and the second following vehicle is automatically followed when there is no adjacent succeeding vehicle. It is preferable to implement control.

  (4) In addition, when the state determination unit determines that the driver is abnormal, it includes notification control means for performing notification control (notification support control) for notifying the abnormality to the outside of the host vehicle at least. It is preferable.

  (5) At this time, the notification control means outputs an operation command different from the normal operation to at least one of the horn device, the headlamp, and the direction indicator, and performs the notification control. It is preferable. For example, in the case of a horn device that is usually operated by a driver, a horn or a headlight is used to sound a horn or sound that the driver cannot ring. In the case of passing, the high beam and the low beam are alternately turned on at a speed that cannot be operated by the driver. Moreover, when using a direction indicator as a hazard lamp, it is making all the direction indicators blink at a speed different from a normal blinking speed.

Herein, the term to "standby control", until it is determined that the preceding vehicle is present, control and continue the automatic travel on the basis of the peripheral information, searches a safe stop position from said peripheral information Control may be included to automatically stop at a safe location.

  According to the disclosed driving support device, if the driver is determined to be abnormal, the vehicle is suddenly stopped or runaway in order to automatically perform the follow-up control on the preceding vehicle traveling in front of the vehicle. Can be prevented. In addition, since the host vehicle travels following the preceding vehicle, it can continue traveling safely, and secondary damage can be reduced. Furthermore, if the preceding vehicle stops during the follow-up control of the own vehicle, the own vehicle stops and the follow-up control ends in accordance with the stop, so that the own vehicle is generally placed in a safe place where the vehicle can stop. Can be stopped. Thereby, secondary damage can be further avoided.

1 is a block diagram illustrating an overall configuration of a driving support apparatus according to an embodiment. (A)-(c) is a figure which illustrates the scene used as the application object of the driving assistance device which concerns on one Embodiment. It is a flowchart which illustrates the control procedure in the driving assistance device concerning one embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. Note that the embodiment described below is merely an example, and there is no intention to exclude various modifications and technical applications that are not explicitly described in the following embodiment.

[1. Device configuration]
The driving support device of this embodiment is mounted on the host vehicle 10 shown in FIG. The driving support device automatically controls the host vehicle 10 when the driver driving the host vehicle 10 becomes difficult to drive, assists driving on behalf of the driver, and other surrounding vehicles, pedestrians, etc. Implement support control to notify the abnormality.

  The assistance control is controlled by a vehicle ECU (electronic control unit) 1 mounted on the host vehicle 10. Here, first, devices connected to the input side and the output side of the vehicle ECU 1 will be described in order. As shown in FIG. 1, the host vehicle 10 is provided with a camera 11, a radar 12, a communication device 13, and a driver state detection sensor 14 that are connected to the input side of the vehicle ECU 1. Further, the host vehicle 10 is provided with an engine 21, an automatic brake device 22, an automatic steering device 23, a horn device 24, a headlamp 25, and a direction indicator 26 connected to the output side of the vehicle ECU 1.

  The camera (information acquisition means) 11 is a front camera that captures an image ahead of the host vehicle 10, a left rear camera and a right rear camera that captures left and right rear images of the host vehicle 10, and the like. Peripheral information is acquired. An image (still image) captured by the camera 11 is transmitted as image data to the vehicle ECU 1 as needed, and image processing is performed on each image data in the vehicle ECU 1. The surrounding information acquired by the camera 11 is road information such as position information, white line information, and signal information of other vehicles that run before and after the host vehicle 10, for example.

  The radar (information acquisition means) 12 is a laser radar, a millimeter wave radar, or the like, for example, and acquires peripheral information of the host vehicle 10. The radar 12 sends out laser waves or the like to the front and rear of the host vehicle 10 and receives the reflected waves to acquire the surrounding information of the host vehicle 10. The peripheral information acquired by the radar 12 is, for example, the presence / absence information of another vehicle, the distance to the other vehicle, the angle (that is, relative position) and speed (relative speed) information, the position information of the utility pole, building, and the like. Each information detected by the radar 11 is transmitted to the vehicle ECU 1 as needed.

  The communication device (information acquisition unit) 13 is a processing device that functions as road-to-vehicle communication that receives peripheral information from a roadside device provided on a road via an antenna provided in the host vehicle 10. The roadside device is a beacon device that transmits, for example, traffic jam information, traffic information for each lane, regulation information such as temporary stop, traffic condition information at a blind spot position, and the like. The communication device 13 is also a processing device that functions as vehicle-to-vehicle communication that communicates with other vehicles around the host vehicle 10 directly via an antenna or via a repeater (not shown). The peripheral information acquired here is information related to position information, speed information, and an operation state (for example, whether the blinker is operated) of the other vehicle. Each information received in the communication device 13 is transmitted to the vehicle ECU 1 as needed.

  The navigation device 14 detects the current position of the host vehicle 10 via an antenna from a GPS satellite, or detects the traveling speed of the host vehicle 10 or provides route guidance to the destination using a GPS, a speed sensor, a gyroscope, or the like. Etc. The navigation device 14 incorporates map data including detailed road information. This map data includes, for example, information on the shape of the road, the number of lanes, the lane width, and the like. Information on the current position, road information, and the like acquired by the navigation device 14 are transmitted to the vehicle ECU 1 as needed.

  The driver state detection sensor 15 detects the state of the driver driving the host vehicle 10. The driver state detected here includes, for example, the driver's driving posture, heartbeat state, and respiratory state. The driving posture of the driver is grasped by, for example, imaging the driver's posture and eyes (movement of eyes) while driving with a camera that images the driver installed in the vehicle. The heart rate state of the driver is grasped by detecting the heart rate of the driver holding the steering wheel, for example, using an electrode built in the steering wheel. Further, the breathing state of the driver is grasped by observing a change in the detection value of the load sensor built in the seat seat on which the driver is seated. The method for detecting the state of the driver is not particularly limited as long as the state determination unit 2 described later can determine whether or not the driver is in a difficult driving state.

  The engine 21 is a drive source of the host vehicle 10, and driving force generated by the engine 21 is transmitted to driving wheels via a power transmission path (not shown). The engine 21 controls the fuel injection amount, the injection timing, the throttle opening degree, and the like by the vehicle control unit 4 described later, thereby controlling the driving force of the host vehicle 10. Here, the engine 21 is illustrated as a drive source of the host vehicle 10, but the host vehicle 10 is not limited to the engine 21 alone as a drive source, and a hybrid electric vehicle using an engine and a motor as a drive source, An electric vehicle using only a motor as a drive source may be used.

  The automatic brake device 22 includes a brake device and a brake actuator, and automatically applies a braking force to each wheel regardless of a driver's brake operation. The brake device is a general brake device such as a full-air drum brake that generates a braking force (braking force) on the front wheels and the rear wheels using air pressure in accordance with the depression of the brake pedal by the driver. The brake actuator generates a braking force of an arbitrary magnitude on each wheel as an automatic brake based on a command from the vehicle control unit 4 described later, apart from a brake operation by the driver.

  The automatic steering device 23 includes a steering and a steering actuator, and automatically controls the steering angle regardless of the driver's steering operation. Steering is a general steering device that changes the direction of wheels according to a steering operation by a driver. The steering actuator changes the direction of the wheels as automatic steering based on a command from the vehicle control unit 4 described later, separately from the steering operation by the driver.

  The horn device 24 is a notification device that emits sound (horn) and notifies the outside of the vehicle, for example, when a horn switch built in the steering wheel is operated. Normally, the horn device 24 is operated by a driver as needed, and the horn switch is energized only while the horn switch is being operated and continues to sound the horn. Regardless of the driver's switch operation, the horn switch is automatically operated.

  The headlamps 25 are illumination devices that are provided on the left and right sides of the front surface of the host vehicle 10 and illuminate the front of the host vehicle 10. There are two types of the headlight 25, a high beam and a low beam. A notification that informs the outside of the vehicle by performing so-called passing that blinks the high beam while the low beam is lit (that is, alternately turns on the low beam and the high beam). It also functions as a device.

  The headlamp 25 is turned on or a high beam and a low beam are switched by operating a head lamp switch provided in the steering, for example. Passing is performed, for example, only while the headlamp switch is pulled forward, and is usually performed by a driver's operation. Here, the headlamp 25 is automatically subjected to passing at a high beam blinking speed different from the normal, based on a command from the notification control unit 5 described later.

  The direction indicators 26 are notification devices that are provided at least at both the left and right ends of the front and rear of the host vehicle 10 and notify other vehicles and the like of the traveling direction of the host vehicle 10. In the direction indicator 26, for example, when a winker switch provided on the steering wheel is operated, either the left or right direction indicator 26 blinks to indicate the traveling direction to the outside of the vehicle. Further, the direction indicator 26 operates as a hazard lamp by operating a hazard switch provided separately from the blinker switch so that all the direction indicators 26 blink. Here, the direction indicator 26 is automatically operated as a hazard lamp at a flashing speed different from the normal on the basis of a command from the notification control unit 5 described later.

  The vehicle ECU 1 is a CPU that executes various arithmetic processes, a ROM that stores programs and data necessary for its control, a RAM that temporarily stores arithmetic results in the CPU, and signals to and from the outside A computer having an input / output port and the like.

[2. Control configuration]
In the vehicle ECU 1 of the present embodiment, when the driver driving the host vehicle 10 is in a difficult driving state, driving support control for safely stopping the host vehicle 10 and notification support for notifying the surroundings of an abnormality of the host vehicle 10 Control (notification control) is performed. In order to realize each control described above, the vehicle ECU 1 functions as a state determination unit 2, a function element as a control determination unit 3, a function element as a vehicle control unit 4, and a notification control unit 5. And functional elements.

  The state determination unit 2 determines whether or not there is an abnormality in the driver's state (health state) based on the information transmitted from the driver state detection sensor 25 (that is, whether or not the driver is in a difficult driving state). To do. Here, “the driver has an abnormality” means that, for example, the driver's heart rate has stopped, the driver has died, or the driver has been in deep sleep (ie, coma This means a state where it is difficult to drive the host vehicle 10 or a state where the host vehicle 10 cannot be driven at all.

  When the state determination unit 2 determines that the driver is abnormal, the determination result is transmitted to the control determination unit 3 and the notification control unit 5. On the other hand, when the state determination unit 2 determines that the driver is not abnormal (normal), the determination result is transmitted to the vehicle control unit 4. The determination by the state determination unit 2 is continuously performed even if a determination result that the driver is abnormal once appears.

  When the state determination unit 2 determines that the driver is abnormal, the control determination unit 3 performs driving support control based on the peripheral information acquired from the camera 11, the radar 12, the communication device 13, and the navigation device 14. This is to determine the requirements for doing so. Note that when the state determination unit 2 determines that the state of the driver is normal, the determination result by the state determination unit 2 is not transmitted to the control determination unit 3, and therefore the determination by the control determination unit 3 is not performed.

  The control determination unit 3 first determines whether there is a preceding vehicle that travels ahead of the host vehicle 10. If it is determined that there is a preceding vehicle, as shown in FIGS. 2A to 2C, the preceding vehicle travels in the same lane as the host vehicle 10 (hereinafter referred to as the host lane 41) (hereinafter referred to as the following vehicle). It is determined whether the vehicle is a first preceding vehicle 31) or a preceding vehicle (hereinafter referred to as a second preceding vehicle 32) traveling in a lane adjacent to the own lane 41 (hereinafter referred to as an adjacent lane 42). The first preceding vehicle 31 and the second preceding vehicle 32 are targeted to the nearest one of the preceding vehicles that run ahead of the host vehicle 10.

  When it is determined that there are a plurality of the preceding preceding vehicles, it is determined whether each preceding vehicle is the first preceding vehicle 31 or the second preceding vehicle 32. Since the second preceding vehicle 32 may exist when the host vehicle 10 is traveling on a road 40 having two or more lanes on one side, first, whether the road 40 on which the host vehicle 10 is traveling is more than one lane on one side. A determination as to whether or not the preceding vehicle is the first preceding vehicle 31 or the second preceding vehicle 32 may be omitted by adding a determination of whether or not.

  When it is determined that only the first preceding vehicle 31 exists in front of the host vehicle 10, it is determined that the first preceding vehicle 31 is a control target. Also, as shown in FIGS. 2A and 2B, when it is determined that both the first preceding vehicle 31 and the second preceding vehicle 32 exist, the first preceding vehicle regardless of the inter-vehicle distance from the host vehicle 10. It is determined that 31 is a control target. That is, when information indicating that the first preceding vehicle 31 and the second preceding vehicle 32 exist while traveling on a road with two or more lanes on one side, the first leading vehicle 31 is given priority.

As shown in FIG. 2C, when it is determined that only the second preceding vehicle 32 exists in front of the host vehicle 10, the host vehicle 10 further enters the adjacent lane 42 on which the second leading vehicle 32 travels. Also, it is determined whether or not there is another vehicle traveling behind (hereinafter referred to as an adjacent succeeding vehicle 33). When it is determined that there is no adjacent succeeding vehicle 33, it is determined that the second preceding vehicle 32 is a control target, and when it is determined that the adjacent subsequent vehicle 33 exists, it is determined that there is no control target.
On the other hand, when it is determined that there is no preceding vehicle traveling in front of the host vehicle 10, it is determined that there is no control target. These determination results are transmitted to the vehicle control unit 4.

  The vehicle control unit 4 automatically performs follow-up control so that the host vehicle 10 follows the control target determined by the control determination unit 3. Further, when the control determination unit 3 determines that there is no control target, standby control is automatically performed. Furthermore, when the determination result that the state of the driver is normal is transmitted by the state determination unit 2, the vehicle control unit 4 stops all the support control if any of the support control is being performed. Alternatively, if no support control is performed, nothing is performed as it is (no support control is performed).

  First, the follow-up control will be described. The vehicle control unit 4 performs the vehicle speed control for controlling the vehicle speed of the host vehicle 10 and the steering angle control for controlling the steering angle, so that the preceding vehicles 31 and 32 (hereinafter referred to as the following vehicle 30) to be controlled are controlled. Follow-up control is performed for this. The vehicle control unit 4 controls the vehicle speed of the host vehicle 10 by controlling the driving force of the engine 21 and the braking force of the automatic brake device 22 according to the vehicle speed of the following vehicle 30 and follows the following vehicle 30. . Further, the direction of the wheels is controlled by controlling the steering actuator of the automatic steering device 23 in accordance with the right / left turn of the following vehicle 30 to follow the following vehicle 30. Thereby, the own vehicle 10 can continue driving | running | working safely.

  Further, the vehicle control unit 4 stops the host vehicle 10 and terminates the follow-up control once the follow-up preceding vehicle 30 stops once following the follow-up preceding vehicle 30. That is, if the own vehicle 10 stops once during the follow-up control, even if the follow-up preceding vehicle 30 starts running again, the vehicle control unit 4 does not perform the follow-up control, and the own vehicle 10 does not follow the follow-up preceding vehicle 30 ( In other words, the host vehicle 10 continues to stop). Thereby, the own vehicle 10 can stop at a safe place.

  The “safe place” here means, for example, a place where there is a stop sign on a general road, a place where a stop for waiting for a signal, a parking lot, etc., and a service area on a highway. , Parking area, tollgate, etc. In other words, the “safe place” generally means a place where the following vehicle is difficult to make a rear-end collision and the vehicle can be stopped safely. It does not mean only roadside belts and parking lots.

  Further, the vehicle control unit 4 uses the stop information (for example, stop position and stop timing) of the follow-up preceding vehicle 30 and the surrounding information (road information) when the host vehicle 10 stops in accordance with the stop of the follow-up preceding vehicle 30. Based on this, it is more preferable to stop the host vehicle 10 at an appropriate place at an appropriate timing. For example, when the following vehicle 30 stops while waiting for a signal, if the own vehicle 10 stops simultaneously with the following vehicle 30, the distance between the following vehicle 30 and the following vehicle 30 may be too long. In order to avoid such a situation, the vehicle control unit 4 stops the host vehicle 10 at a timing slightly later than the stop timing of the follow-up preceding vehicle 30 and sets the inter-vehicle distance from the follow-up preceding vehicle 30 as compared to when traveling. Control may be performed so that the vehicle speed becomes shorter, or deceleration may be started at the same timing as the following vehicle 30 and the deceleration may be different from that of the following vehicle 30 during deceleration.

  Next, standby control will be described. The standby control is control performed when there is no preceding vehicle that can immediately follow when the driver is in a difficult driving state. Here, the vehicle control unit 4 does not collide with the host vehicle 10 based on the peripheral information acquired by the camera 11 and the radar 12 until the control determination unit 3 determines that the control target exists as standby control. Implement automatic running control that automatically runs at a reduced speed.

  For example, when traveling on a road with two or more lanes on one side such as an expressway, if it is determined that there is no control object because there is an adjacent succeeding vehicle 33 although there is a second preceding vehicle 32, the speed of the host vehicle 10 is The speed is reduced to a level that does not cause a rear-end collision, and waiting for the adjacent succeeding vehicle 33 to pass the host vehicle 10 (wait). And if this adjacent succeeding vehicle 33 overtakes the own vehicle 10, this adjacent succeeding vehicle 33 can become a new second preceding vehicle 32. Further, for example, when traveling on a general road and continuously running at a low speed so that another vehicle enters the front of the host vehicle 10 and entering the front of the host vehicle 10, the other vehicle The following vehicle 30 is determined.

  When the host vehicle 10 stops once during execution of such standby control, the vehicle control unit 4 ends the standby control and keeps the host vehicle 10 stopped. For example, when the host vehicle 10 is traveling automatically based on the surrounding information, if there is a red signal ahead, the host vehicle 10 is automatically stopped, and then the host vehicle 10 is driven even if the signal changes to blue. Keep it in a stopped state.

  When the state determination unit 2 determines that the driver is abnormal, the notification control unit 5 controls the horn device 24, the headlamp 25, and the direction indicator 26, and other vehicles around the host vehicle 10. Or the pedestrian or the like is notified of the abnormality of the host vehicle 10. Here, the notification control unit 5 issues a command to the horn device 24 to sound a horn with a rhythm or sound different from normal. Also, the headlamp 25 is instructed to perform a high beam blinking speed different from the normal one, and the direction indicator 26 blinks the omnidirectional indicator 26 at a blinking speed different from the normal one. Issue a command to function as a hazard lamp.

  The notification control unit 5 may be configured to control at least one of the horn device 24, the headlamp 25, and the direction indicator 26 instead of controlling all of them. . Moreover, you may add the structure which alert | reports to a vehicle interior using the audio | voice function, buzzer, etc. of the navigation apparatus 14. FIG. This is effective when the driver is in a coma.

[3. flowchart]
Next, the control procedure implemented by vehicle ECU1 is demonstrated using the flowchart of FIG. This flowchart operates at a predetermined control cycle. Each of the following steps is performed by each function (means) assigned to the hardware of the computer being operated by software (computer program).

  When the driver turns on an ignition switch (not shown), the support control apparatus starts the following control flow. As shown in FIG. 3, first, in step S10, the driver state detection sensor 15 detects the driver state. Next, in step S20, it is determined whether or not the driver is abnormal. Here, when it is determined that the driver is abnormal, it is difficult for the driver to continue driving, and thus assist control is performed.

  In step S <b> 30, the alarm control unit 5 controls the horn device 24, the headlamp 25, and the direction indicator 26, and notification control for notifying the surroundings of the abnormality of the host vehicle 10 is performed. This notification control is continued until it is determined that the driver is not abnormal (normal) or until the ignition switch is turned off after the host vehicle 10 stops. In step S <b> 40, the surrounding information of the host vehicle 10 is acquired by the camera 11, the radar 12, the communication device 13, and the navigation device 14.

  Next, in step S50, it is determined whether or not the flag F is F = 1. The flag F is a variable for checking the current control state of the host vehicle 10, and F = 0 corresponds to the fact that no control is being performed, F = 1 corresponds to the execution of follow-up control, F = 2 corresponds to standby control. The initial value is set to F = 0. When the process proceeds to step S50 for the first time, since the flag F is F = 0, the process proceeds to step S60 and it is determined whether or not there is a preceding vehicle that travels ahead of the host vehicle 10.

  Here, when it is determined that there is a preceding vehicle, it is determined whether or not the preceding vehicle is the first preceding vehicle 31 traveling on the own lane 41 in step S70. If the preceding vehicle is the first preceding vehicle 31, the first preceding vehicle 31 is set as the following preceding vehicle 30, and the following control is performed in step S80. In step S90, the flag F is set to F = 1, and this control cycle ends and the process returns.

  If the driver remains abnormal in the next control cycle, the process proceeds from step S50 to step S100, and it is determined whether the following vehicle 30 has stopped. If the following vehicle 30 is traveling, the process proceeds to step S80 and the following control is continued. Further, when the follow-up preceding vehicle 30 stops, the process proceeds to step S110, the host vehicle 10 is also stopped, the follow-up control is finished, and this control flow is finished. In other words, when the process proceeds to step S110, the host vehicle 10 has traveled to a safe place and stopped at the safe place, and therefore continues to stop at that place (stopped and held). At this time, since the notification control started in step S30 is continuing, it is in a state of continuously notifying the surroundings that the own vehicle 10 that continues to stop is in an abnormal state.

  On the other hand, when it is determined in step S60 that there is no preceding vehicle, the process proceeds to step S115, and it is determined whether or not the host vehicle 10 has stopped. If the host vehicle 10 is traveling, the process proceeds to step S120 and standby control is performed. Then, in step S130, the flag F is set to F = 2, and this control cycle ends and the process returns.

  If it is determined in step S70 that the preceding vehicle is not the first preceding vehicle 31, the process proceeds to step S72, and it is determined whether or not the preceding vehicle is the second preceding vehicle 32 traveling in the adjacent lane 42. If the preceding vehicle is the second preceding vehicle 32, it is determined in the subsequent step S74 whether there is no adjacent succeeding vehicle 33 or not. If there is no adjacent succeeding vehicle 33, the second preceding vehicle 32 is set as the following preceding vehicle 30, the following control is performed in step S80, the flag F is set to F = 1 in step S90, and this control cycle ends. Then return.

  On the other hand, when the preceding vehicle is not an adjacent preceding vehicle in step S72 (that is, when the vehicle is traveling in a lane not adjacent to the own lane 41), and when the adjacent succeeding vehicle 33 exists in step S74, step S115 is performed. It is determined whether or not the host vehicle 10 has stopped. If the host vehicle 10 is traveling, the process proceeds to step S120 and standby control is performed. Then, in step S130, the flag F is set to F = 2, and this control cycle ends and the process returns.

  When standby control is performed in step S120, the process proceeds from step S50 to step S60 again in the subsequent control cycle, and the presence or absence of a preceding vehicle is determined. Here, if the following vehicle 30 is present, the process proceeds to step S80, and the standby control is switched to the following control. If there is no following vehicle 30, it is determined in step S115 whether the host vehicle 10 has stopped. Thus, the standby control is continued as long as the host vehicle 10 is traveling, and automatic traveling based on the peripheral information is performed. On the other hand, if the host vehicle 10 is stopped due to waiting for a signal during the standby control, for example, the process proceeds from step S115 to step S135, the standby control is ended, and the control flow ends. That is, the host vehicle 10 continues to stop on the spot and does not start again.

  If it is determined in step S20 that the driver is not abnormal (normal), the process proceeds to step S140, and it is determined whether or not the flag F is F = 0. If the flag F is F = 0, the control cycle ends and the process returns. If the flag F is not F = 0 (that is, if follow-up control or standby control is being performed), the process proceeds to step S150, stops all control (ie, notification control and follow-up control or standby control), The flag F is reset to F = 0, and this control cycle ends and returns. That is, even if it is determined that the driver is abnormal once, the support control is stopped if the determination is reversed.

[4. Action / Effect]
Next, the assistance control according to the present embodiment will be described with reference to FIGS. FIGS. 2A to 2C illustrate a case where the host vehicle 10 is traveling on a two-lane highway. When it is determined that the driver driving the host vehicle 10 is in a difficult driving state while traveling on such a road 40, notification to the surroundings is started by a horn, passing or a hazard lamp. Further, the front of the host vehicle 10 is searched by the camera 11, the radar 12, etc., and the presence or absence of a preceding vehicle is determined. Note that the range S _F indicated by a chain line in the figure is a forward search area, it is determined that this be put into forward search area S _F "with the preceding vehicle."

As shown in FIG. 2 (a) and (b), when the second preceding vehicle 32 traveling on the first preceding vehicle 31 and the adjacent lane 42 running the own lane 41 in the forward search area S _F is detected Regardless of the inter-vehicle distance from the host vehicle 10 (even if the second preceding vehicle 32 is closer to the host vehicle 10), the first leading vehicle 31 is set as the following vehicle 30. Then, follow-up control is performed on the first preceding vehicle 31. As described above, when the first preceding vehicle 31 exists, the follow-up control is performed on the first leading vehicle 31 to suppress unnecessary lane changes and the vehicle 10 can continue to travel safely.

On the other hand, as shown in FIG. 2 (c), when only the second preceding vehicle 32 in the forward search area S _F is detected, the rear of the vehicle 10 is searched by the camera 11 and the radar 12 or the like, adjacent the follower vehicle The presence or absence of 33 is determined. The range S _RR and S _RL indicated by a one-dot chain line in the drawing is a right backward search area and left backward search area respectively, is determined as where "there adjacent vehicle behind" if placed in the right backward search area S _RR is .

Since there is an adjacent succeeding vehicle 33 in the scene shown in FIG. 2 (c), if the lane change is attempted to follow the second preceding vehicle 32 in this state, the host vehicle 10 may come into contact with the adjacent succeeding vehicle 33. There is. Therefore, in this state, the follow-up control to the second preceding vehicle 32 is not performed, and the standby control is performed until the adjacent succeeding vehicle 33 is not detected in the right rear search area _SRR . If the adjacent succeeding vehicle 33 enters the forward search area S _F overtaking vehicle 10 in turn is determined that the vehicle was adjacent vehicle behind 33 is newly second preceding vehicle. At this time, if the first preceding vehicle 31 is not detected and no new adjacent succeeding vehicle is detected, the new second preceding vehicle is set as the following preceding vehicle 30 and the following control is started.

  And if the following vehicle 30 stops in a service area, a toll gate, etc. while the own vehicle 10 is performing follow-up control, the own vehicle 10 will also stop and it will continue to stop as it is. At this time, the own vehicle 10 continues to notify by a horn, passing, or a hazard lamp, and the surrounding people see this to understand that some abnormality has occurred.

  Therefore, according to the driving support apparatus according to the present embodiment, when it is determined that the driver is abnormal, the follow-up control is automatically performed on the preceding vehicle (following preceding vehicle) 30 traveling in front of the host vehicle 10. Therefore, it is possible to prevent a situation in which the host vehicle 10 suddenly stops or runs away. Further, since the vehicle 10 travels following the preceding vehicle 30, it can continue traveling safely as long as the preceding vehicle 30 continues traveling safely, and secondary damage can be avoided or reduced. .

  Furthermore, if the preceding vehicle 30 stops during the follow-up control of the own vehicle 10, the own vehicle 10 stops and the follow-up control ends in accordance with the stop, so that it is generally a safe place where the vehicle can stop. The host vehicle 10 can be stopped. Thereby, secondary damage can be further avoided.

  When the first preceding vehicle 31 and the second preceding vehicle 32 exist, it is determined that the first preceding vehicle 31 is a control target, and the first preceding vehicle 31 is automatically subjected to follow-up control. Therefore, unnecessary lane changes are suppressed, and safety can be further improved.

  When only the information on the second preceding vehicle 32 is acquired, it is determined whether or not there is an adjacent succeeding vehicle 33 that travels behind the host vehicle 10 in the adjacent lane 42 on which the second preceding vehicle 32 travels. Follow-up control is automatically performed on the second preceding vehicle 32 when the vehicle 33 is not present. Therefore, even when the lane change is performed and the second preceding vehicle 32 is followed, the lane can be changed after confirming the safety behind the vehicle, so that the safety of the host vehicle 10 can be further improved. Also, the safety of the adjacent succeeding vehicle 33 can be ensured.

  In addition, when the state determination unit 2 determines that the driver is abnormal, notification control for notifying the abnormality of the host vehicle 10 is performed, so that some abnormality occurs in the people around the host vehicle 10. I can inform you that In addition, it is possible to notify the following vehicle 30 that is subject to follow-up control that the following vehicle that is following (that is, the host vehicle 10) is abnormal.

  In this notification control, the horn device 24, the headlamp 25, and the direction indicator 26 are used, and the horn is sounded by an operation different from the normal operation, and the passing and hazard lamps are turned on. Can be sure to know that is happening. Further, as described above, the communication device 13 may be used for vehicle-to-vehicle communication, and information on an abnormal situation may be transmitted to other vehicles by vehicle-to-vehicle communication.

  Further, when it is determined by the state determination unit 2 that the driver is abnormal, if there is no tracking preceding vehicle 30 for performing the tracking control, based on the peripheral information obtained from the camera 11, the radar 12, or the like Standby control is performed. Therefore, even when the following vehicle 30 does not exist, the safety of the host vehicle 10 can be ensured to the minimum.

  Furthermore, here, when it is newly determined that the follow-up preceding vehicle 30 exists during the standby control, the standby control is switched to the follow-up control, so that the vehicle 10 can continue to travel safely, Can be stopped in a safe place.

[5. Others]
Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.
In the above-described embodiment, the case where the vehicle 40 is traveling on the one-sided two-lane road 40 is illustrated. The road may be three or more lanes on one side.

Moreover, when it determines with both the 1st preceding vehicle 31 and the 2nd preceding vehicle 32 existing, the structure which makes the preceding vehicle nearer the own vehicle 10 the follow preceding vehicle 30 may be sufficient. In this case, the distance between the follower preceding vehicle 30 and the vehicle 10 is short, that follow the preceding vehicle 30 is disappeared from forward search area S _F (can not be searched) fear is eliminated, to reliably initiate a follow-up control it can.

In addition, all of the camera 11, the radar 12, the communication device 13, and the navigation device 14 that acquire the surrounding information of the host vehicle 10 may not be mounted, and any one or a plurality of them may be provided. In addition, peripheral information may be acquired from devices other than these.
The notification method is not limited to the above-described method, and notification may be performed using devices other than the horn device 24, the headlamp 25, and the direction indicator 26. Further, even when the horn device 24, the headlamp 25, and the direction indicator 26 are used, the notification does not necessarily have to be performed with an operation different from the normal operation.

  In addition, the notification start timing is not limited to the above-described one. For example, when a driver abnormality is determined, notification is first made by passing or a hazard lamp is turned on, and the horn is sounded after the own vehicle 10 stops. Good. In this way, by providing a step in the notification, it is possible to minimize the influence on the surroundings when the determination of whether or not the driver is abnormal is covered.

Further, the standby control is not limited to the above-described one. For example, the standby control searches for a safe stop position while automatically driving the host vehicle 10 based on surrounding information, and automatically stops the vehicle at a safe place. May be. That is, the standby control may be a conventional control.
Further, the determination by the control determination unit 3 described in the above embodiment may be performed by the vehicle control unit 4 and the control determination unit 3 may be omitted.

1 Vehicle ECU
2 State determination unit (state determination means)
3 Control determination unit 4 Vehicle control unit (vehicle control means)
5. Notification control unit (notification control means)
10 own vehicle 11 camera (information acquisition means)
12 Radar (information acquisition means)
13 Communication device (information acquisition means)
DESCRIPTION OF SYMBOLS 14 Driver state detection sensor 21 Engine 22 Automatic brake device 23 Automatic steering device 24 Horn device 25 Headlamp 26 Direction indicator 30 Following vehicle (preceding vehicle)
31 First preceding car (leading car)
32 Second preceding car (leading car)
33 Adjacent following vehicle 40 Road 41 Own lane 42 Adjacent lane

Claims (5)

State determination means for determining the state of the driver driving the host vehicle;
Information acquisition means for acquiring peripheral information including information of a preceding vehicle traveling in front of the host vehicle;
Vehicle control means for performing tracking control including vehicle speed control and steering angle control so that the host vehicle travels following the preceding vehicle,
The vehicle control means automatically starts the follow-up control for the preceding vehicle based on the peripheral information acquired by the information acquisition means when the state determination means determines that the driver is abnormal. and, if the information the preceding vehicle stop information by the acquisition means during the implementation of the following control is obtained the stops the vehicle to exit the follow-up control, the vehicle as the preceding vehicle started to run again Is stopped,
When the preceding vehicle for performing the follow-up control does not exist , a driving support device is provided that performs standby control that automatically reduces the speed to the extent that a rear-end collision is not caused based on the surrounding information. . The preceding vehicle includes a first preceding vehicle that travels in the same lane as the host vehicle and a second preceding vehicle that travels in an adjacent lane adjacent to the lane,
The vehicle control means, when the information determining means acquires information on the first preceding vehicle and the second preceding vehicle when the state determining means determines that the driver is abnormal, The driving support apparatus according to claim 1, wherein the follow-up control is automatically performed on one preceding vehicle. The vehicle control means, when it is determined by the state determination means that the driver is abnormal, when only the information on the second preceding vehicle is acquired by the information acquisition means, the second preceding vehicle is It is determined whether or not there is an adjacent succeeding vehicle traveling behind the host vehicle in the adjacent lane that travels, and the follow-up control is automatically performed on the second preceding vehicle when there is no adjacent succeeding vehicle. The driving support device according to claim 2, characterized in that: The system further comprises notification control means for performing notification control for notifying the abnormality outside the host vehicle when the driver determines that the driver is abnormal by the state determination means. 4. The driving support device according to any one of 3 above. The notification control means outputs an operation command different from a normal operation to at least one of a horn device, a headlamp, and a direction indicator, and performs the notification control, The driving support device according to claim 4 .

Images