JP2019142300A - Vehicle control device - Google Patents

Abstract

To suppress that sudden deceleration or steering is performed according to behavior of peripheral vehicles, and thus, discomfort is given to an operator, and vehicular ride comfort is deteriorated.SOLUTION: A vehicle control device for controlling travel of a vehicle has: a peripheral vehicle detection part 10b which detects peripheral vehicles around an own vehicle; an operation information reception part which receives operation information concerning acceleration and deceleration and/or steering of the peripheral vehicles by operators; a speed distribution setting part 10d which sets limit speed distribution in which an upper limit of an acceptable relative speed is regulated around the peripheral vehicles; and a control part 10e which so limits a speed and/or steering of the own vehicle as to satisfy said limit speed distribution set by the speed distribution setting part 10d. The speed distribution setting part 10d estimates change in travel behavior of the peripheral vehicles based on operation information received by the operation information reception part, and sets said limit speed distribution according to this.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a vehicle control device, and more particularly to a vehicle control device that controls traveling of a vehicle.

  Japanese Patent Laying-Open No. 2006-218935 (Patent Document 1) describes a vehicle travel support device. In this vehicle travel support device, when an object in the traveling direction of the host vehicle is detected, it is predicted whether a safe distance is secured when the object is closest to the host vehicle, and the safe distance cannot be secured. When predicted, the driving support control is executed. In this vehicular travel support device, the direction of an object is detected, and a safe distance is set according to this direction.

  However, the control by the vehicle driving support apparatus described in Patent Document 1 is merely for the purpose of avoiding a collision, and overtakes or overtakes the preceding vehicle (parked vehicle) during normal driving of the host vehicle. In some cases, it is not sufficient to avoid collisions. In other words, when overtaking and overtaking the preceding vehicle, it is necessary to maintain a sufficient interval between the preceding vehicle (parked vehicle) without causing anxiety to the driver.

  In order to achieve this object, the applicant sets a speed limit distribution that defines an allowable upper limit value of a plurality of relative speeds around an object such as a preceding vehicle, and automatically avoids exceeding the allowable upper limit value. A vehicle control device for controlling the vehicle speed and steering of the vehicle has been developed (International Patent Application JP2016 / 075233). By mounting such a vehicle control device, it is possible to maintain a sufficient distance from the target object even when overtaking and overtaking the target object such as a preceding vehicle, and less likely to cause driver anxiety. Control is successful.

JP 2006-218935 A

However, even in the control in which the speed limit distribution defining the allowable upper limit values of a plurality of relative speeds is set around the object, when the preceding vehicle as the object decelerates or changes the lane, It becomes difficult to maintain a sufficient distance from the preceding vehicle. For this reason, depending on the behavior of the preceding vehicle, if the vehicle is relatively suddenly decelerated or steered so that a sufficient distance is maintained, the driver may feel uneasy, or the ride comfort of the vehicle may deteriorate. There is.
Therefore, according to the present invention, a vehicle in which sudden deceleration or steering is performed in the host vehicle due to the behavior of the surrounding vehicle, and the driver can be prevented from feeling uneasy or the ride comfort of the vehicle is deteriorated. The object is to provide a control device.

  In order to solve the above-described problems, the present invention is a vehicle control device that controls the traveling of a vehicle, and includes a surrounding vehicle detection unit that detects a surrounding vehicle that travels around the host vehicle, and the surrounding vehicle detection. An operation information receiving unit that receives operation information related to acceleration / deceleration and / or steering by a driver of the surrounding vehicle from a surrounding vehicle detected by the unit, and an allowable area around the surrounding vehicle detected by the surrounding vehicle detecting unit A speed distribution setting unit that sets a speed limit distribution that defines an upper limit value of the relative speed, and a control unit that controls the speed and / or steering of the host vehicle so as to satisfy the speed limit distribution set by the speed distribution setting unit The speed distribution setting unit estimates a change in the driving behavior of the surrounding vehicle based on the operation information received by the operation information receiving unit, and sets the speed limit distribution accordingly. It is characterized.

  In the present invention configured as described above, the surrounding vehicle detection unit detects the surrounding vehicle running around the host vehicle, and the operation information receiving unit is configured to perform acceleration / deceleration and / or steering by the driver of the surrounding vehicle. The operation information regarding is received from surrounding vehicles. The speed distribution setting unit sets a speed limit distribution that defines an upper limit value of an allowable relative speed around the surrounding vehicle detected by the surrounding vehicle detection unit. The speed distribution setting unit estimates a change in driving behavior of the surrounding vehicle based on the operation information received by the operation information receiving unit, and sets a speed limit distribution according to the change. The speed and / or steering of the host vehicle is controlled so as to satisfy the distribution.

  According to the present invention configured as described above, the speed distribution setting unit estimates the change in the driving behavior of the surrounding vehicle based on the operation information received by the operation information receiving unit, and the speed limit distribution is set accordingly. Is done. For this reason, the driver of the surrounding vehicle performs acceleration / deceleration and steering operations, and responds to changes in the driving behavior of the surrounding vehicles sooner than dealing with this after the operation appears in the driving behavior of the surrounding vehicles. A speed limit distribution can be set, and sudden deceleration and steering can be avoided. As a result, it is possible to prevent the driver from feeling uneasy and the ride comfort of the vehicle from getting worse.

In the present invention, preferably, the speed distribution setting unit sets a plurality of speed limit distributions according to the distance from the surrounding vehicle.
According to the present invention configured as described above, since a plurality of speed limit distributions are set according to the distance from the surrounding vehicle, the speed limit can be set stepwise in accordance with the distance from the surrounding vehicle. For this reason, it is possible to set a smooth travel route that satisfies the speed limit distribution, and the ride comfort of the host vehicle can be improved.

  In the present invention, preferably, when the speed distribution setting unit is estimated that a surrounding vehicle traveling in front of the host vehicle decelerates a predetermined amount or more based on the operation information received by the operation information receiving unit. The speed limit in the traveling direction in the speed limit distribution is reduced.

  According to the present invention configured as described above, the speed limit in the traveling direction in the speed limit distribution is reduced when the surrounding vehicle in front is estimated to decelerate a predetermined amount or more, so that the speed limit distribution is satisfied. Therefore, the deceleration of the host vehicle is started early. For this reason, braking for satisfying the speed limit distribution can be executed gently, and the ride comfort of the host vehicle can be improved.

  In the present invention, preferably, the speed distribution setting unit is configured to estimate that a surrounding vehicle traveling in front of the host vehicle changes the lane in the first direction based on the operation information received by the operation information receiving unit. Lowers the speed limit in at least the first direction in the speed limit distribution.

  According to the present invention configured as described above, when it is estimated that the surrounding vehicle ahead changes the lane in the first direction, the speed limit in at least the first direction in the speed limit distribution is reduced. Since the speed limit in the first direction is thus reduced, it becomes difficult to set a travel route that avoids and overtakes the surrounding vehicle ahead in the first direction to change the lane in the first direction. Unreasonable overtaking by driving assistance can be regulated.

  The present invention also relates to a vehicle control method for controlling the running of a vehicle, detecting a surrounding vehicle running around the host vehicle, and accelerating or decelerating by the driver of the surrounding vehicle from the detected surrounding vehicle. And / or an operation information receiving step for receiving operation information related to steering, and a speed distribution setting step for setting a speed limit distribution defining an upper limit value of an allowable relative speed around the surrounding vehicle detected in the surrounding vehicle detecting step. And a control step for controlling the speed and / or steering of the host vehicle so as to satisfy the speed limit distribution set in the speed distribution setting step. In the speed distribution setting step, in the operation information receiving step Changes in the driving behavior of surrounding vehicles are estimated based on the received operation information, and a speed limit distribution is set accordingly. .

  According to the vehicle control device of the present invention, it is possible to suppress the driver from feeling anxiety or the ride comfort of the vehicle from being suddenly decelerated or steered by the own vehicle due to the behavior of surrounding vehicles. be able to.

It is a block diagram of the vehicle control apparatus by embodiment of this invention. It is a control block diagram of the vehicle control apparatus by embodiment of this invention. It is explanatory drawing of the 1st target driving | running route set in the vehicle control apparatus by embodiment of this invention. It is explanatory drawing of the 2nd target driving | running route set in the vehicle control apparatus by embodiment of this invention. It is explanatory drawing of the 3rd target driving | running route set in the vehicle control apparatus by embodiment of this invention. It is explanatory drawing of the obstacle avoidance by correction | amendment of the travel route in the vehicle control apparatus by embodiment of this invention. It is explanatory drawing which shows the relationship between the distance between the surrounding vehicle and the own vehicle at the time of avoiding a surrounding vehicle in the vehicle control apparatus by embodiment of this invention, and the allowable upper limit of a relative speed. It is explanatory drawing of the vehicle model in the vehicle control apparatus by embodiment of this invention. It is a process flowchart of the driving assistance control in the vehicle control apparatus by embodiment of this invention. It is a process flowchart of the speed limit distribution setting process in the vehicle control apparatus by embodiment of this invention. In the vehicle control apparatus by embodiment of this invention, it is a figure which shows the change of the permissible upper limit of relative speed when the surrounding vehicle applies a sudden brake. In the vehicle control apparatus by embodiment of this invention, it is a figure which shows the change of the speed limit distribution when a surrounding vehicle applies a sudden brake. In the vehicle control apparatus by embodiment of this invention, it is a figure which shows the change of the permissible upper limit value of relative speed when the surrounding vehicle changes lanes. In the vehicle control apparatus by embodiment of this invention, it is a figure which shows the change of the speed limit distribution when the surrounding vehicle changes lanes. It is a figure which shows the modification of a correction coefficient setting when a surrounding vehicle applies a sudden brake. It is a figure which shows the modification of speed limit distribution in case the surrounding vehicle is going to change a lane.

  Hereinafter, a vehicle control apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings. First, with reference to FIG.1 and FIG.2, the structure of a vehicle control apparatus is demonstrated. FIG. 1 is a configuration diagram of the vehicle control device, and FIG. 2 is a control block diagram of the vehicle control device.

  The vehicle control apparatus 100 according to the present embodiment is configured to provide different driving support controls to a vehicle 1 (see FIG. 3 and the like) on which the vehicle control apparatus 100 is mounted by a plurality of driving support modes. The driver can select a desired driving support mode from a plurality of driving support modes.

  As shown in FIG. 1, the vehicle control device 100 is equipped with a vehicle control arithmetic unit (ECU) 10, a plurality of sensors and switches, a plurality of control systems, and a user input for a driving support mode mounted on the vehicle 1. A driver operation unit (not shown) is provided. The plurality of sensors and switches include a camera 21 that captures images outside the passenger compartment, a millimeter wave radar 22, a vehicle speed sensor 23 that detects the behavior of the vehicle, a positioning system 24, a navigation system 25, and an inter-vehicle communication system 26. The plurality of control systems include an engine control system 31, a brake control system 32, and a steering control system 33.

  The ECU 10 shown in FIG. 1 includes a computer having a CPU, a memory for storing various programs, an input / output device, and the like. The ECU 10 generates an engine control system 31, a brake control system 32, a steering wheel based on a driving support mode selection signal and a set vehicle speed signal received from a driver operation unit (not shown), and signals received from a plurality of sensors and switches. The control system 33 is configured to be able to output request signals for appropriately operating the engine system, the brake system, and the steering system, respectively.

  The camera 21 images the front of the vehicle 1 and outputs the captured image data. Based on the image data, the ECU 10 detects objects (for example, vehicles, pedestrians, roads, lane markings (lane boundaries, white lines, yellow lines), traffic signals, traffic signs, stop lines, intersections, preceding vehicles, obstacles, etc. ). In addition, a vehicle exterior camera that captures images of the side and rear of the vehicle 1 can be provided. Furthermore, the vehicle interior camera which images the driver | operator during driving can also be provided in a vehicle.

The millimeter wave radar 22 is a measuring device that measures the position and speed of an object (particularly, a preceding vehicle, a parked vehicle, a pedestrian, an obstacle, etc.), and transmits radio waves (transmitted waves) toward the front of the vehicle 1. Then, the reflected wave generated by reflecting the transmission wave by the object is received. The millimeter wave radar 22 measures the distance between the vehicle 1 and the object (for example, the inter-vehicle distance) and the relative speed of the object with respect to the vehicle 1 based on the transmitted wave and the received wave. In the present embodiment, the millimeter wave radar 22 includes a front radar that detects an object in front of the vehicle 1, a side radar that detects an object of a side object, and an object behind the vehicle 1. A rear radar is provided for detecting. Further, instead of the millimeter wave radar 22, a distance from the object and a relative speed may be measured using a laser radar, an ultrasonic sensor, or the like. Moreover, you may comprise a position and speed measuring apparatus using a some sensor.
The vehicle speed sensor 23 is configured to detect the absolute speed of the vehicle 1.

The positioning system 24 is a GPS system and / or a gyro system, and detects the position of the vehicle 1 (current vehicle position information).
The navigation system 25 stores map information therein and can provide the map information to the ECU 10. The ECU 10 specifies roads, intersections, traffic signals, buildings, etc. existing around the vehicle 1 (particularly in the forward direction) based on the map information and the current vehicle position information. The map information may be stored in the ECU 10.

  The inter-vehicle communication system 26 is a communication system between vehicles. Between the own vehicle and a vehicle traveling in the vicinity, vehicle position information, traveling speed information, acceleration / deceleration by the driver, It is configured to exchange operation information related to steering and the like. The inter-vehicle communication system 26 can acquire information such as the position, speed, and operation by the driver of a vehicle that is stopped or traveling relatively far on the travel route of the host vehicle.

  The engine control system 31 is a controller that controls the engine of the vehicle 1. When it is necessary to accelerate or decelerate the vehicle 1, the ECU 10 outputs an engine output change request signal that requests the engine control system 31 to change the engine output so as to obtain the target acceleration / deceleration.

  The brake control system 32 is a controller for controlling the brake device of the vehicle 1. When it is necessary to decelerate the vehicle 1, the ECU 10 outputs a brake request signal that requests the brake control system 32 to generate a braking force to the vehicle 1 so as to obtain a target acceleration / deceleration.

  The steering control system 33 is a controller that controls the steering device of the vehicle 1. When it is necessary to change the traveling direction of the vehicle 1, the ECU 10 outputs a steering direction change request signal that requests the steering control system 33 to change the steering direction so that the target snake angle is obtained.

  As shown in FIG. 2, the ECU 10 includes a single CPU that functions as an input processing unit 10a, a surrounding vehicle detection unit 10b, a target travel route calculation unit 10c, a speed distribution setting unit 10d, and a control unit 10e. In the present embodiment, a single CPU is configured to execute a plurality of the above functions. However, the present invention is not limited to this, and a plurality of CPUs can be configured to execute these functions.

The input processing unit 10a is configured to process input information input from each sensor, the navigation system 25, and the inter-vehicle communication system 26. The input processing unit 10a functions as an image analysis unit that analyzes an image of the camera 21 that captures the traveling road surface and detects a traveling lane (parting lines on both sides of the lane) in which the host vehicle is traveling.
The surrounding vehicle detection unit 10b is configured to detect a surrounding vehicle or the like traveling around the host vehicle based on input information from the millimeter wave radar 22, the camera 21, the inter-vehicle communication system 26, and the like.
The target travel route calculation unit 10c is configured to calculate a target travel route of the vehicle based on input information from the millimeter wave radar 22, the camera 21, each sensor, and the like.

  The speed distribution setting unit 10d sets a speed limit distribution that defines an upper limit value of an allowable relative speed around the surrounding vehicle. For example, the speed distribution setting unit 10d distributes the upper limit line of the allowable relative speed at which the host vehicle 1 can travel with respect to the surrounding vehicle (restriction) when the surrounding vehicle detection unit 10b detects a vehicle to be avoided in the vicinity. Set the speed distribution. Even when the surrounding vehicle detection unit 10b detects a target to be avoided other than the vehicle, the speed distribution setting unit 10d sets a speed limit distribution around the target.

  Furthermore, the control unit 10e controls the speed and steering of the host vehicle so as to satisfy a speed limit distribution that is an upper limit line of an allowable relative speed at which the vehicle can travel. Specifically, the control unit 10e calculates a corrected travel route by correcting the target travel route calculated by the target travel route calculation unit 10c so as to satisfy the speed limit distribution. Next, a travel route that satisfies a predetermined constraint condition is selected from the corrected travel routes that satisfy the speed limit distribution. Further, the control unit 10e is configured to determine a travel route that minimizes a predetermined evaluation function from the selected travel routes as an optimum corrected travel route. That is, the control unit 10e calculates a corrected travel route based on the speed limit distribution, a predetermined evaluation function, and a predetermined constraint condition. Further, in the present embodiment, the constraint conditions for determining the optimum corrected travel route are set as appropriate based on the selected driving support mode and the driving situation by the driver. In addition, this invention can also be comprised so that the control part 10e may produce | generate the driving | running route which satisfies speed limit distribution, without using a constraint condition and an evaluation function.

  Further, the control unit 10e generates a request signal for at least one of the engine control system 31, the brake control system 32, and the steering control system 33 in order to travel on the determined optimum corrected travel route, Output.

  Next, the driving support mode provided in the vehicle control apparatus 100 according to the present embodiment will be described. In this embodiment, four modes are provided as the driving support mode. That is, it is executed when none of the driving assistance modes is selected, ie, the speed limit mode that is the driver steering mode, the preceding vehicle follow-up mode that is the automatic steering mode, the automatic speed control mode that is the driver steering mode. Basic control mode is provided.

<Previous vehicle follow-up mode>
The preceding vehicle following mode is basically an automatic steering mode in which the vehicle 1 follows the preceding vehicle while maintaining a predetermined inter-vehicle distance corresponding to the vehicle speed between the vehicle 1 and the preceding vehicle. 100 automatic steering control, speed control (engine control, brake control), obstacle avoidance control (speed control and steering control) are involved.

  In the preceding vehicle follow-up mode, different steering control and speed control are performed depending on whether or not the both ends of the lane can be detected and whether there is a preceding vehicle. Here, both ends of the lane are both ends of the lane in which the vehicle 1 travels (division lines such as white lines, road edges, curbstones, median strips, guardrails, etc.), and the boundaries between adjacent lanes and sidewalks. is there. The input processing unit 10 a included in the ECU 10 detects both ends of the lane from image data captured by the camera 21. Moreover, you may detect a lane both ends from the map information of the navigation system 25. FIG. However, for example, when the vehicle 1 is not on a road on which the vehicle 1 is maintained but travels on a plain where no lane exists, or when both ends of the lane cannot be detected due to poor reading of image data from the camera 21 or the like.

  In the present embodiment, the ECU 10 as the preceding vehicle detection unit detects the preceding vehicle from the image data from the camera 21 and the measurement data from the front radar of the millimeter wave radar 22. Specifically, another vehicle traveling ahead is detected as a surrounding vehicle based on image data obtained by the camera 21. Furthermore, in the present embodiment, when the inter-vehicle distance between the vehicle 1 and the surrounding vehicle is equal to or less than a predetermined distance (for example, 400 to 500 m), the other vehicle is detected as a preceding vehicle based on the measurement data obtained by the millimeter wave radar 22. The

  In the preceding vehicle follow-up mode, the target travel route is detected when a peripheral target to be avoided is detected by the input processing unit 10a regardless of the presence or absence of a preceding vehicle (peripheral vehicle) and whether or not both ends of the lane can be detected. Is corrected and obstacles (neighboring targets) are automatically avoided.

<Automatic speed control mode>
The automatic speed control mode is a driver steering mode in which the speed is controlled so as to maintain a predetermined set vehicle speed (constant speed) preset by the driver, and automatic speed control (engine) by the vehicle control device 100 is performed. Control, brake control), but steering control is not performed. In this automatic speed control mode, the vehicle 1 travels so as to maintain the set vehicle speed, but can be increased beyond the set vehicle speed by depressing the accelerator pedal by the driver. Further, when the driver performs a brake operation, the driver's intention is prioritized and the vehicle is decelerated from the set vehicle speed. In addition, when catching up with the preceding vehicle, the speed is controlled so as to follow the preceding vehicle while maintaining the inter-vehicle distance according to the vehicle speed, and when there is no preceding vehicle, the speed control is performed so that it returns to the set vehicle speed again. Is done.

<Speed limit mode>
The speed limit mode is a driver steering mode for controlling the speed of the vehicle 1 so that the vehicle speed of the vehicle 1 does not exceed the speed limit set by the speed sign or the set speed set by the driver. With speed control (engine control). The speed limit may be specified by the ECU 10 performing image recognition processing on the speed indicator imaged by the camera 21 or the speed display image data on the road surface, or may be received by wireless communication from the outside. In the speed limit mode, even when the driver depresses the accelerator pedal so as to exceed the speed limit, the vehicle 1 is increased only to the speed limit.

<Basic control mode>
The basic control mode is a mode (off mode) when no driving support mode is selected, and automatic steering control and speed control by the vehicle control device 100 are not performed. However, when there is a possibility that the vehicle 1 collides with a surrounding vehicle such as an oncoming vehicle, control for avoiding the collision is executed. Further, these collision avoidances are similarly executed in the preceding vehicle following mode, automatic speed control, and speed limit mode.

  Next, a plurality of travel routes calculated by the vehicle control device 100 according to the present embodiment will be described with reference to FIGS. 3 to 5 are explanatory diagrams of the first travel route to the third travel route, respectively. In the present embodiment, the target travel route calculation unit 10c provided in the ECU 10 is configured to repeatedly calculate the following first travel route R1 to third travel route R3 in terms of time (for example, 0.1 Every second). In the present embodiment, the ECU 10 calculates a travel route from a current time until a predetermined period (for example, 3 seconds) elapses based on information such as sensors. The travel route Rx (x = 1, 2, 3) is specified by the target position (Px_k) and the target speed (Vx_k) of the vehicle 1 on the travel route (k = 0, 1, 2,..., N). ). Further, at each target position, target values are specified for a plurality of variables (acceleration, acceleration change amount, yaw rate, steering angle, vehicle angle, etc.) in addition to the target speed.

  3 to 5, the travel route (the first travel route to the third travel route) is a periphery related to a target (an obstacle such as a surrounding vehicle or a pedestrian) on or around the travel route on which the vehicle 1 travels. The calculation is performed based on the shape of the traveling path, the traveling locus of the preceding vehicle, the traveling behavior of the vehicle 1, and the set vehicle speed without considering the detection information of the target. Thus, in this embodiment, since the information on the peripheral target is not taken into consideration in the calculation, the overall calculation load of the plurality of travel routes can be reduced.

Hereinafter, for easy understanding, each travel route calculated when the vehicle 1 travels on the road 5 including the straight section 5a, the curve section 5b, and the straight section 5c will be described. The road 5 is composed of left and right lanes 5 _L and 5 _R. At present, the vehicle 1 is assumed to be traveling on the lane 5 _L of the straight sections 5a.

(First travel route)
As shown in FIG. 3, the first travel route R <b> 1 is set for a predetermined period so that the vehicle 1 can keep traveling in the lane 5 </ b> _L that is the travel route in accordance with the shape of the road 5. Specifically, the first traveling route R1 is straight section 5a, the vehicle 1, 5c is set to maintain a running near the center of the lane 5 _L, the vehicle 1 in the curve section 5b is higher than the center in the width direction of the lane 5 _L Is also set to travel on the inner side or the in side (the center O side of the curvature radius L of the curve section).

Target traveling path calculator 10c performs the image recognition processing of the image data around the vehicle 1 captured by the camera 21, detects the lane end portions 6 _L, 6 _R. Both ends of the lane are lane markings (white lines, etc.) and road shoulders as described above. Furthermore, the target traveling path calculator 10c based on the detected lane end portions 6 _L, 6 _R, calculates the radius of curvature L of the lane width W, and the curve section 5b lane 5 _L. Further, the lane width W and the curvature radius L may be acquired from the map information of the navigation system 25. Further, the target travel route calculation unit 10c reads the speed sign S and the speed limit displayed on the road surface from the image data. As described above, the speed limit may be acquired by wireless communication from the outside.

Target traveling path calculator 10c is straight section 5a, the 5c, the central portion in the width direction of the vehicle 1 the center in the width direction of the lane end portions 6 _L, 6 _R (e.g., center of gravity position) so as to pass through, the A plurality of target positions P1_k for one travel route R1 are set.

On the other hand, the target traveling path calculator 10c is the curve section 5b, in the longitudinal direction of the center position P1_c curve section 5b, sets the widthwise center position of the lane 5 _L maximum displacement amount Ws to the in-side. This displacement amount Ws is calculated based on the curvature radius L, the lane width W, and the width dimension D of the vehicle 1 (a prescribed value stored in the memory of the ECU 10). Then, the target travel route calculation unit 10c sets a plurality of target positions P1_k on the first travel route R1 so as to smoothly connect the center position P1_c of the curve section 5b and the center positions in the width direction of the straight sections 5a and 5c. Note that the first travel route R1 may be set on the in side of the straight sections 5a and 5c even before and after entering the curve section 5b.

  In principle, the target speed V1_k at each target position P1_k on the first travel route R1 is set to a speed set by the driver or a predetermined set vehicle speed (constant speed) preset by the vehicle control device 100. However, if this set vehicle speed exceeds the speed limit obtained from the speed indicator S or the like or the speed limit defined according to the curvature radius L of the curve section 5b, the target speed of each target position P1_k on the travel route V1_k is limited to a lower speed limit of the two speed limits. Furthermore, the target travel route calculation unit 10c appropriately corrects the target position P1_k and the target vehicle speed V1_k according to the current behavior state of the vehicle 1 (that is, vehicle speed, acceleration, yaw rate, steering angle, lateral acceleration, etc.). For example, when the current vehicle speed is significantly different from the set vehicle speed, the target vehicle speed is corrected so that the vehicle speed approaches the set vehicle speed.

(Second travel route)
Further, as shown in FIG. 4, the second travel route R2 is set for a predetermined period so as to follow the travel locus of the preceding vehicle 3 (neighboring vehicles). Based on the image data from the camera 21, the measurement data from the millimeter wave radar 22, and the vehicle speed of the vehicle 1 from the vehicle speed sensor 23, the target travel route calculation unit 10 c and the position of the preceding vehicle 3 on the lane 5 _L on which the vehicle 1 travels and The speed is continuously calculated and stored as preceding vehicle locus information. Based on the preceding vehicle locus information, the traveling locus of the preceding vehicle 3 is set as the second traveling route R2 (target position P2_k, target speed V2_k). Set.

(Third travel route)
As shown in FIG. 5, the third travel route R3 is set for a predetermined period based on the current driving state of the vehicle 1 by the driver. That is, the third travel route R3 is set based on the position and speed estimated from the current travel behavior of the vehicle 1.
The target travel route calculation unit 10c calculates a target position P3_k of the third travel route R3 for a predetermined period based on the steering angle, yaw rate, and lateral acceleration of the vehicle 1. However, the target travel route calculation unit 10c corrects the target position P3_k so that the calculated third travel route R3 does not approach or intersect the lane end when the both ends of the lane are detected.

  Further, the target travel route calculation unit 10c calculates a target speed V3_k of the third travel route R3 for a predetermined period based on the current vehicle speed and acceleration of the vehicle 1. If the target speed V3_k exceeds the speed limit acquired from the speed indicator S or the like, the target speed V3_k may be corrected so as not to exceed the speed limit.

  Next, the relationship between the driving support mode and the travel route in the vehicle control apparatus 100 according to the present embodiment will be described. In the present embodiment, when the driver selects one driving support mode, the travel route is selected according to the selected driving support mode.

When the preceding vehicle following mode is selected, if both ends of the lane are detected, the first travel route is applied regardless of the presence or absence of the preceding vehicle. In this case, the set vehicle speed that has been set is the target speed.
On the other hand, when the preceding vehicle follow-up mode is selected, the second travel route is applied when both ends of the lane are not detected and the preceding vehicle is detected. In this case, the target speed is set according to the vehicle speed of the preceding vehicle. In addition, when the preceding vehicle follow-up mode is selected, the third travel route is applied when neither end of the lane is detected and no preceding vehicle is detected.

  Further, the third travel route is applied when the automatic speed control mode is selected. The automatic speed control mode is a mode in which the speed control is automatically executed as described above, and the set set vehicle speed becomes the target speed. Further, steering control is executed based on the operation of the steering wheel by the driver.

  The third travel route is also applied when the speed limit mode is selected. The speed limit mode is also a mode in which the speed control is automatically executed as described above, and the target speed is set in accordance with the depression amount of the accelerator pedal by the driver within the range of the limit speed or less. Further, steering control is executed based on the operation of the steering wheel by the driver.

  In addition, when the basic control mode (off mode) is selected, the third travel route is applied. The basic control mode is basically the same as the state where the speed limit is not set in the speed limit mode.

Next, with reference to FIGS. 6 to 8, the travel route correction process executed in the control unit 10e of the ECU 10 according to the present embodiment will be described. FIG. 6 is an explanatory diagram of obstacle avoidance by correcting the travel route. FIG. 7 is an explanatory view showing the relationship between the distance between the surrounding vehicle and the host vehicle when avoiding the surrounding vehicle and the allowable upper limit value of the relative speed, and FIG. 8 is an explanatory view of the vehicle model.
In FIG. 6, the vehicle 1 is traveling on a travel path (lane) 7, and is trying to pass the vehicle 3, passing the traveling or stopped vehicle 3 (peripheral vehicle).

  In general, when passing (or overtaking) an obstacle on the road or near the road (for example, a preceding car, a parked vehicle, a pedestrian, etc.), the driver of the vehicle 1 A predetermined clearance or interval (lateral distance) is maintained between the vehicle 1 and the obstacle, and the vehicle 1 is decelerated to a speed at which the driver feels safe. Specifically, in order to avoid the danger that the preceding vehicle suddenly changes course, the pedestrian comes out from the blind spot of the obstacle, or the door of the parked vehicle opens, The relative speed is reduced.

  In general, when approaching the preceding vehicle from behind, the driver of the vehicle 1 adjusts the speed (relative speed) according to the inter-vehicle distance (vertical distance) along the traveling direction. Specifically, when the inter-vehicle distance is large, the approach speed (relative speed) is maintained high, but when the inter-vehicle distance is small, the approach speed is decreased. The relative speed between the two vehicles is zero at a predetermined inter-vehicle distance. This is the same even if the preceding vehicle is a parked vehicle.

  In this way, the driver drives the vehicle 1 so that there is no danger while considering the relationship between the distance between the obstacle and the vehicle 1 (including the lateral distance and the longitudinal distance) and the relative speed. ing.

Therefore, in the present embodiment, as shown in FIG. 6, the vehicle 1 is located around the obstacle (lateral region, rear region, And over the front area) or at least between the obstacle and the vehicle 1 is configured to set a two-dimensional distribution (limited speed distribution 40) that defines an allowable upper limit value for the relative speed in the traveling direction of the vehicle 1. Yes. In the speed limit distribution 40, an allowable upper limit value V _lim of the relative speed is set at each point around the obstacle. Thus, the speed distribution setting unit 10 d sets a plurality of speed limit distributions 40 according to the distance from the surrounding vehicle 3. In this embodiment, in all the driving support modes, the travel route is corrected so that the relative speed of the vehicle 1 with respect to the obstacle does not exceed the allowable upper limit value V _lim in the speed limit distribution 40. Further, as will be described later, the speed limit distribution 40 set around the obstacle depends on information received from the surrounding vehicle via the inter-vehicle communication system 26 when the obstacle is a surrounding vehicle. A different one is set.

As can be seen from FIG. 6, in principle, the speed limit distribution 40 is such that the allowable upper limit value of the relative speed becomes smaller as the lateral distance and the longitudinal distance from the obstacle become smaller (as the obstacle gets closer). Is set. That is, the speed limit distribution 40 is set as a plurality of equal relative speed lines connecting points having the same allowable upper limit value. Equivalent relative speed lines a, b, c, and d indicate speed limit distributions 40 having allowable upper limit values V _lim of 0 km / h, 20 km / h, 40 km / h, and 60 km / h, respectively. In this example, each speed limit distribution 40 is set to a substantially rectangular shape. As described above, when the obstacle (peripheral target) to be avoided is recognized by the input processing unit 10a, the speed distribution setting unit 10d has an upper limit line of an allowable relative speed at which the vehicle can travel with respect to the obstacle. A speed limit distribution 40 is set. Then, the control unit 10e corrects the target travel route calculated by the target travel route calculation unit 10c so as to satisfy the speed limit distribution 40.

  The speed limit distribution 40 does not necessarily have to be set over the entire periphery of the obstacle. At least the rear side of the obstacle and the one side in the lateral direction of the obstacle where the vehicle 1 exists (in FIG. 6, the vehicle 3 To the right area). Further, the speed limit distribution 40 may be set asymmetrical.

As shown in FIG. 7, when the vehicle 1 travels at a certain relative speed with respect to the obstacle (in the example of FIG. 6, the relative speed is the absolute speed of the vehicle 1 because the vehicle 3 that is an obstacle is stopped). The allowable upper limit value V _lim is set to increase in a quadratic function with respect to the distance from the obstacle. That is, the allowable upper limit value V _lim [km / h] of the relative speed is equal to the lateral clearance X from the obstacle.
V _lim = αk ₁ (X−D _X0 ) ² , (X ≧ D _X0 ) (1)
V _lim = 0 (X <D _X0 )
Is set by

In the above formula (1), k ₁ is a gain coefficient related to the degree of change in V _lim with respect to the lateral clearance X, and is set depending on the type of obstacle and the like. The safe distance D _X0 can also be set depending on the type of obstacle. As an example, in the present embodiment, the safety distance D _X0 = 0.2 [m] is set. Furthermore, when the obstacle is a surrounding vehicle, the correction coefficient α is a coefficient that is changed according to operation information or the like by the driver of the surrounding vehicle received from the surrounding vehicle via the inter-vehicle communication system 26. is there. The setting of the correction coefficient α will be described later.

Further, as shown in the equation (1), the allowable upper limit value V _lim is 0 (zero) km / h until the clearance X is D _X0 (safety distance) in the lateral direction of the obstacle, and is equal to or higher than D _X0. Increases in a quadratic function. That is, to ensure safety, when the clearance X is D _X0 or less, the allowable relative speed of the vehicle 1 becomes zero. On the other hand, when the clearance X is equal to or greater than D _X0 , the larger the clearance, the higher the relative speed of the vehicle 1 is allowed to pass.

On the other hand, in the vertical direction of the obstacle (the traveling direction of the vehicle 1), the allowable upper limit value V _lim [km / h] of the relative speed is equal to the distance Y in the traveling direction to the obstacle.
V _lim = βk ₂ (Y−D _Y0 ) ² / Vs, (Y ≧ D _Y0 ) (2)
V _lim = 0 (Y <D _Y0 )
Is set by

In the above formula (2), Vs [km / h] is the traveling speed of the vehicle 1, also, k ₂ is related to the degree of change in V _lim with respect to the traveling direction of the distance Y (distance to the obstacle) Gain It is a coefficient and is set depending on the type of obstacle. The safe distance D _Y0 can also be set depending on the type of obstacle. As an example, in the present embodiment, the safety distance D _Y0 = 2 [m] is set. Furthermore, when the obstacle is a surrounding vehicle, the correction coefficients α and β are changed according to operation information received by the driver of the surrounding vehicle received from the surrounding vehicle via the inter-vehicle communication system 26. It is a coefficient. The setting of the correction coefficients α and β will be described later.

As expressed in the equation (2), the allowable upper limit value V _lim is 0 (zero) km in the traveling direction (vertical direction) of the _host vehicle until the vertical distance Y is D _Y0 (safety distance). / H, increasing in a quadratic function above D _Y0 . That is, to ensure safety, the relative speed allowed for the vehicle 1 becomes zero when the distance Y to the obstacle is D _Y0 or less. On the other hand, when the distance Y is greater than D _Y0 , the vehicle 1 is allowed to approach at a higher relative speed as the distance Y increases. In the vertical direction, the allowable upper limit value V _lim is set to be inversely proportional to the traveling speed Vs of the host vehicle 1. That is, the higher the traveling speed Vs of the host vehicle 1 is, the longer the braking distance of the host vehicle 1 is. Therefore, considering this, the traveling speed Vs is increased and the allowable upper limit value V _lim is decreased. As a result, the higher the traveling speed Vs of the host vehicle 1, the lower the upper limit value V _{lim of the} relative speed allowed for the same distance Y.

In the present embodiment, V _lim is defined to be a quadratic function of X and Y in both the horizontal direction and the vertical direction. However, the present invention is not limited to this, and other functions (for example, a linear function) are used. May be defined. Further, with reference to FIG. 7, the lateral allowable upper limit V _lim obstacles, and it has been described vertical allowable upper limit V _lim behind the obstacle, everything, including the vertical direction in front of the obstacle It can set similarly about the radial direction. At that time, the coefficient k and the safety distance D ₀ can be set according to the direction from the obstacle.

The speed limit distribution 40 can be set based on various parameters. As parameters, for example, the relative speed between the vehicle 1 and the obstacle, the type of the obstacle, the traveling direction of the vehicle 1, the moving direction and moving speed of the obstacle, the length of the obstacle, the absolute speed of the vehicle 1 and the like are taken into consideration. Can do. That is, the coefficient k and the safety distance D ₀ can be selected based on these parameters.

  In the present embodiment, the obstacle includes a vehicle, a pedestrian, a bicycle, a cliff, a groove, a hole, a fallen object, and the like. Furthermore, vehicles can be distinguished by automobiles, trucks, and motorcycles. Pedestrians can be distinguished by adults, children and groups.

  As shown in FIG. 6, when the vehicle 1 is traveling on the travel path 7, the input processing unit 10 a built in the ECU 10 of the vehicle 1 is based on the image data from the camera 21 (the vehicle 3). Is detected. At this time, the type of obstacle (in this case, vehicle, pedestrian) is specified.

  Further, the input processing unit 10 a calculates the position, relative speed, and absolute speed of the obstacle (vehicle 3) with respect to the vehicle 1 based on the measurement data of the millimeter wave radar 22 and the vehicle speed data of the vehicle speed sensor 23. The position of the obstacle includes a y-direction position (vertical distance) along the traveling direction of the vehicle 1 and an x-direction position (horizontal distance) along the lateral direction orthogonal to the traveling direction.

The speed distribution setting unit 10d built in the ECU 10 sets the speed limit distribution 40 for all detected obstacles (the vehicle 3 in the case of FIG. 6). Then, the control unit 10e corrects the travel route so that the speed of the vehicle 1 does not exceed the allowable upper limit value V _lim of the speed limit distribution 40. The control part 10e correct | amends the target driving | running route applied according to the driving assistance mode which the driver | operator selected with the avoidance of an obstruction.

  That is, when the vehicle 1 travels on the target travel route, if the target speed exceeds a permissible upper limit value defined by the speed limit distribution 40 at a certain target position, the target speed is decreased without changing the target position. (Path Rc1 in FIG. 6), whether the target position is changed on the detour path so that the target speed does not exceed the allowable upper limit without changing the target speed (path Rc3 in FIG. 6), the target position and the target speed Are both changed (route Rc2 in FIG. 6).

  For example, FIG. 6 shows a case where the calculated target travel route R is a route that travels at a center position (target position) in the width direction of the travel path 7 at 60 km / h (target speed). In this case, the parked vehicle 3 is present as an obstacle ahead, but as described above, this obstacle is not taken into consideration in the calculation stage of the target travel route R in order to reduce the calculation load.

When the vehicle travels on the target travel route R, the vehicle 1 crosses the equal relative speed lines d, c, c, d of the speed limit distribution 40 in order. That is, the vehicle 1 traveling at 60 km / h enters an area inside the equal relative speed line d (allowable upper limit value V _lim = 60 km / h). Therefore, the control unit 10e corrects the target travel route R so as to limit the target speed at each target position of the target travel route R to the allowable upper limit value _Vlim or less, and generates a corrected target travel route Rc1. That is, in the corrected target travel route Rc1, the target speed gradually decreases to less than 40 km / h as the vehicle 3 is approached so that the target vehicle speed is less than or equal to the allowable upper limit value V _{lim at} each target position. Thereafter, as the vehicle 3 moves away from the vehicle 3, the target speed is gradually increased to the original 60 km / h.

  Further, the target travel route Rc3 does not change the target speed (60 km / h) of the target travel route R, and is therefore set to travel outside the equal relative speed line d (corresponding to a relative speed of 60 km / h). Route. In order to maintain the target speed of the target travel route R, the control unit 10e corrects the target travel route R so as to change the target position so that the target position is positioned on or outside the equal relative speed line d, A target travel route Rc3 is generated. Therefore, the target speed of the target travel route Rc3 is maintained at 60 km / h, which is the target speed of the target travel route R.

  The target travel route Rc2 is a route in which both the target position and the target speed of the target travel route R are changed. In the target travel route Rc2, the target speed is not maintained at 60 km / h, but gradually decreases as the vehicle 3 approaches, and then gradually increases to the original 60 km / h as the vehicle 3 moves away. Is done.

The correction for changing only the target speed without changing the target position of the target driving path R as in the target driving path Rc1 can be applied to a driving support mode that involves speed control but does not involve steering control ( For example, automatic speed control mode, speed limit mode, basic control mode).
Further, the correction for changing only the target position without changing the target speed of the target driving route R as in the target driving route Rc3 can be applied to the driving support mode with steering control (for example, following the preceding vehicle). mode).
Further, the correction that changes both the target position and the target speed of the target travel route R as in the target travel route Rc2 can be applied to a driving support mode that involves speed control and steering control (for example, a preceding vehicle following mode). ).

  Next, the control part 10e built in ECU10 determines an optimal correction | amendment driving | running route based on sensor information etc. from the correction | amendment driving | running route which can be set. That is, the control unit 10e determines an optimum corrected travel route from among the settable corrected travel routes based on a predetermined evaluation function and a predetermined constraint condition.

  The ECU 10 stores the evaluation function J, the constraint conditions, and the vehicle model in the memory. When determining the optimal corrected travel route, the control unit 10e calculates an optimal corrected travel route in which the evaluation function J has an extreme value within a range that satisfies the constraint conditions and the vehicle model (optimization process).

  The evaluation function J has a plurality of evaluation factors. The evaluation factors in this example are, for example, speed (vertical direction and horizontal direction), acceleration (vertical direction and horizontal direction), acceleration change amount (vertical direction and horizontal direction), yaw rate, lateral position relative to the lane center, vehicle angle, steering It is a function for evaluating the quality of a plurality of travel routes obtained by correcting the target travel route for corners and other soft constraints.

  The evaluation factors include an evaluation factor related to the vertical behavior of the vehicle 1 (vertical evaluation factor: vertical speed, acceleration, acceleration change amount, etc.) and an evaluation factor related to the horizontal behavior of the vehicle 1 (lateral evaluation factor). : Lateral velocity, acceleration, acceleration variation, yaw rate, lateral position relative to the lane center, vehicle angle, steering angle, etc.).

In the present embodiment, the evaluation function J is described by the following equation.

In the equation, Wk (Xk−Xrefk) ² is an evaluation factor, Xk is a physical quantity related to the evaluation factor of the corrected travel route, Xrefk is a physical quantity related to the evaluation factor of the target travel route (before correction), and Wk is a weight value of the evaluation factor (for example, 0 ≦ Wk ≦ 1) (where k = 1 to n). Therefore, the evaluation function J of the present embodiment weights the sum of the squares of the differences in the physical quantity of the corrected travel route with respect to the physical amount of the target travel route (before correction) for the physical quantities of n evaluation factors, and calculates the predetermined period ( For example, it corresponds to the total value over the travel route length of N = 3 seconds.

  In the present embodiment, the evaluation function J has a smaller value as the evaluation of the travel route corrected for the target travel route is higher. Therefore, the travel route for which the evaluation function J has a minimum value is determined by the control unit 10e as the optimum corrected travel route. Is calculated as

  The constraint condition is a condition that the corrected travel route needs to be satisfied. By narrowing down the corrected travel route to be evaluated based on the constraint condition, it is possible to reduce the calculation load required for the optimization process by the evaluation function J. Calculation time can be shortened.

  The vehicle model defines the physical motion of the vehicle 1 and is described by the following motion equation. This vehicle model is a two-wheel model shown in FIG. 8 in this example. By defining the physical motion of the vehicle 1 by the vehicle model, it is possible to calculate a corrected travel route in which a sense of discomfort during travel is reduced, and to optimize the optimization process using the evaluation function J at an early stage. it can.

8 and equations (3) and (4), m is the mass of the vehicle 1, I is the yaw moment of inertia of the vehicle 1, l is the wheel base, l _f is the distance between the vehicle center of gravity and the front axle, and l _r is The distance between the vehicle center of gravity and the rear axle, K _f is the tire cornering power per front wheel, K _r is the tire cornering power per rear wheel, V is the vehicle speed of the vehicle 1, δ is the actual steering angle of the front wheel, β is the side slip angle of the center of gravity of the vehicle, r is the yaw angular velocity of the vehicle 1, θ is the yaw angle of the vehicle 1, y is the lateral displacement of the vehicle 1 with respect to absolute space, and t is time.
As described above, the control unit 10e calculates an optimal corrected travel route that minimizes the evaluation function J from a large number of travel routes, based on the target travel route, the constraint conditions, the vehicle model, and the like.

  Next, with reference to FIG. 9 thru | or FIG. 14, the processing flow of the vehicle control method in the vehicle control apparatus 100 of this embodiment is demonstrated. FIG. 9 is a process flowchart of the driving support control, and FIG. 10 is a process flowchart of the speed limit distribution setting process.

  The ECU 10 repeatedly executes the process flowchart of FIG. 9 every predetermined time (for example, 0.1 seconds). First, the input processing unit 10a of the ECU 10 executes data reading as information acquisition processing in step S10. In the information acquisition process, the ECU 10 acquires information on current vehicle position information, map information, peripheral targets, and the like from the positioning system 24, the navigation system 25, and the inter-vehicle communication system 26, and the camera 21, the millimeter wave radar 22, Sensor information is acquired from the vehicle speed sensor 23 or the like. In addition, in step S10, this invention can also be comprised so that the sensor information from an acceleration sensor, a yaw rate sensor, a driver | operator operation part (it is not shown above) etc. may also be acquired. Further, the present invention may be configured to acquire switch information from a steering angle sensor, an accelerator sensor, a brake sensor (not shown), and the like.

  Further, the ECU 10 detects vehicle operation information (steering angle, accelerator pedal depression amount, brake pedal depression amount, etc.) related to vehicle operation by the driver from the switch information, and further, the behavior of the vehicle 1 from the switch information and sensor information. Travel behavior information (vehicle speed, longitudinal acceleration, lateral acceleration, yaw rate, etc.) is detected.

  The information received from the surrounding vehicle via the inter-vehicle communication system 26 includes a steering angle, an accelerator pedal depression amount, a brake pedal depression amount, etc. as operation information on acceleration / deceleration and steering by the driver of the surrounding vehicle. It is. Therefore, the inter-vehicle communication system 26 functions as an operation information receiving unit that receives operation information from drivers of surrounding vehicles. Further, when the surrounding vehicle is equipped with a vehicle control device such as a driving support device or an automatic driving device, information on the travel route after the present time set in this vehicle control device is also stored in the inter-vehicle communication system 26. Received via.

  Next, ECU10 performs a predetermined target object detection process in step S11 using the various information acquired by the information acquisition process. In the object detection processing, the ECU 10 determines the travel path information (straight section and curve) about the travel path shape around the vehicle 1 and in the front area from the current vehicle position information, map information, information from the inter-vehicle communication system 26 and sensor information. Presence / absence of section, length of each section, radius of curvature of curve section, lane width, position of both ends of lane, number of lanes, presence / absence of intersection, speed limit defined by curve curvature, etc., travel regulation information (speed limit, red signal Etc.), the preceding vehicle locus information (the traveling locus of the preceding vehicle) is detected. In addition, the surrounding vehicle detection unit 10b of the ECU 10 performs peripheral object information (an obstacle on the traveling route) including the surrounding vehicle based on information from the inter-vehicle communication system 26 and sensor information such as the camera 1 as the object detection processing. Presence / absence, type, size, position, etc.). Accordingly, the processing in steps S10 and S11 detects surrounding vehicles that are traveling around the host vehicle, and from the detected surrounding vehicles, operation information regarding acceleration / deceleration and / or steering by the driver of the surrounding vehicle 3 is obtained. It functions as an operation information receiving step that is received via the inter-vehicle communication system 26.

Next, in step S12, the speed distribution setting unit 10d of the ECU 10 executes a speed limit distribution setting process. That is, the speed distribution setting unit 10d sets the speed limit distribution 40 shown in FIG. 6 around a peripheral target such as a peripheral vehicle detected by the peripheral vehicle detection unit 10b in step S11. Therefore, the process in step S12 functions as a speed distribution setting step for setting a speed limit distribution 40 that defines an upper limit value of an allowable relative speed around the surrounding vehicle 3.
Next, in step S13, the target travel route calculation unit 10c of the ECU 10 calculates the target travel route shown in FIGS. 3 to 5 using the travel route information detected in step S11. Further, the control unit 10e corrects the calculated target travel route so as to satisfy the speed limit distribution 40, and calculates a corrected travel route that defines the travel locus and the travel speed along the travel route.

  Further, in step S14, the control unit 10e of the ECU 10 moves to the corresponding control system (engine control system 31, brake control system 32, steering control system 33) so as to travel on the corrected travel route calculated in step S13. Outputs a request signal. Specifically, the ECU 10 generates and outputs a request signal according to target engine, brake, and steering target control amounts specified by the calculated corrected travel route. Accordingly, the processing in steps S13 and S14 functions as a control step for controlling the speed and / or steering of the host vehicle so as to satisfy the set speed limit distribution.

Next, the speed limit distribution setting process executed in step S12 of the flowchart shown in FIG. 9 will be described with reference to FIGS.
FIG. 10 is a flowchart of speed limit distribution setting processing executed as a subroutine of the flowchart shown in FIG. FIG. 11 is a diagram showing a change in the allowable upper limit value of the relative speed when the surrounding vehicle suddenly brakes, and FIG. 12 is a diagram showing a change in the speed limit distribution 40 in this case. FIG. 13 is a diagram showing a change in the allowable upper limit value of the relative speed when the surrounding vehicle changes lanes, and FIG. 14 is a diagram showing a change in the speed limit distribution 40 in this case.

  First, in step S21 of FIG. 10, the peripheral vehicle is based on the operation information by the driver of the peripheral vehicle traveling in front of the host vehicle 1 obtained through the inter-vehicle communication system 26 in step S10 of FIG. Estimate the behavior of For example, when the driver of the surrounding vehicle depresses the brake pedal for a predetermined amount or more, it can be estimated that the driver applies the brake suddenly and the surrounding vehicle decelerates rapidly. Alternatively, when the driver rotates the steering wheel by a predetermined amount or more, it can be estimated that the surrounding vehicle turns a corner or changes lanes. In addition, when the surrounding vehicle is equipped with a vehicle control device such as a driving support device or an automatic driving device, the surrounding vehicle performs lane change or the like from information on the travel route set in the vehicle control device. Can be estimated.

  In addition, the inter-vehicle communication system 26 repeatedly receives operation information from the driver of the surrounding vehicle at predetermined time intervals from the traveling or stopped vehicle around the host vehicle 1. Since this time interval is sufficiently short, for example, when the driver suddenly applies a brake, the surrounding vehicle actually starts to decelerate, which is earlier than when this is detected by the camera 21 or the millimeter wave radar 22 of the host vehicle 1. It is possible to detect the deceleration of the surrounding vehicle.

  In step S22, it is determined whether or not the driver of the surrounding vehicle traveling in front of the host vehicle 1 has suddenly applied the brake. In the present embodiment, it is determined that sudden braking has been applied when the amount of depression of the brake pedal of the surrounding vehicle acquired via the inter-vehicle communication system 26 is greater than or equal to a predetermined amount. Or based on the control signal with respect to the brake actuator with which the surrounding vehicle was equipped, you may determine the presence or absence of the sudden brake in a surrounding vehicle.

If the brake is suddenly applied, the process proceeds to step S23, where the value of the correction coefficient β in the above equation (2) for calculating the allowable upper limit value V _lim of the relative speed is changed. When the process of the flowchart shown in FIG. 10 is started, the correction coefficient values are set to α = 1 and β = 1 as defaults. That is, in the present embodiment, as shown in the graph on the left side of FIG. 11, the correction coefficient β = 1 in the normal state, and the allowable upper limit value V _lim of the relative speed is a predetermined value as the distance Y to the surrounding vehicle increases. The slope increases in a quadratic function. On the other hand, when it is estimated that sudden braking has been applied in the surrounding vehicle ahead, the correction coefficient β is changed to 0.8 = 0.8, and as shown in the graph on the right side of FIG. Thus, the slope at which the allowable upper limit value V _lim of the relative speed increases as a quadratic function is changed to a gentle slope.

  As described above, the speed distribution setting unit 10d estimates a change in the traveling behavior of the surrounding vehicle 3 based on the operation information received by the inter-vehicle communication system 26, and sets the speed limit distribution accordingly. In the present embodiment, when the deceleration of the surrounding vehicle 3 is less than a predetermined value, and when the operation information of the surrounding vehicle is not obtained via the inter-vehicle communication system 26, it is processed as “normal time”, The correction factor defaults to β = 1.

  After setting the value of the correction coefficient β in step S23, the processing in the ECU 10 proceeds to step S26. In step S26, the speed limit distribution 40 is set based on the set correction coefficients α and β (the value of α remains the default), and one process of the flowchart shown in FIG. The processing in returns to the flowchart shown in FIG.

  As the value of the correction coefficient β is changed to a small value in step S23, the speed limit distribution 40 set in step S26 changes from that shown on the left side of FIG. 12 to that shown on the right side. That is, the speed limit distribution 40 is expanded from the normal time (β = 1) shown on the left side of FIG. 12 to the rearward direction from the surrounding vehicle 3 as shown on the right side of FIG. Be changed. Thereby, when it is estimated that the surrounding vehicle 3 traveling in front of the host vehicle 1 decelerates a predetermined amount or more, the speed limit in the travel direction in the speed limit distribution 40 is reduced. Even if the surrounding vehicle 3 decelerates by a predetermined amount or more, the value of the correction coefficient α in the equation (1) is not changed, so the width of the speed limit distribution 40 in the horizontal direction (direction perpendicular to the traveling direction of the host vehicle) is The same as usual.

In the example shown in FIG. 12, when the host vehicle 1 is traveling behind the surrounding vehicle 3 and at a distance Y ₁ , the speed limit is not set in the normal time shown on the left side. On the other hand, when the sudden braking is applied in the surrounding vehicle 3 and the correction coefficient β is changed to 0.8 = 0.8, as shown on the right side of FIG. 12, the host vehicle 1 has an upper limit line of an allowable relative speed of 60 km / h. And the relative speed is limited to 60 km / h. Thus, when the sudden braking is applied in the vicinity of the vehicle 3, for the same distance Y ₁ from nearby vehicle 3, the upper limit of the relative speed allowed is lowered.

  As described above, in this embodiment, when it is estimated that the surrounding vehicle 3 ahead is decelerated by a predetermined amount or more, the upper limit value of the relative speed to be allowed is reduced. The relative speed is limited at an early stage in a sufficiently separated state, and the sudden braking of the surrounding vehicle 3 can be dealt with with a margin. For this reason, when the surrounding vehicle 3 ahead brakes suddenly, the anxiety given to a driver | operator can be reduced.

  On the other hand, if it is determined in step S22 of FIG. 10 that the sudden braking is not applied, the process proceeds to step S24. In step S24, it is determined whether or not the surrounding vehicle 3 is going to change lanes. In this embodiment, when the rotation angle of the steering wheel of the surrounding vehicle acquired via the inter-vehicle communication system 26 is equal to or greater than a predetermined amount, it is determined that the driver of the surrounding vehicle 3 is going to change lanes or the like. Is done. Alternatively, when the surrounding vehicle 3 is provided with a vehicle control device, a lane change or the like of the surrounding vehicle 3 may be determined based on a target travel route set by the vehicle control device.

When the surrounding vehicle 3 is going to change the lane, the process proceeds to step S25, where the value of the correction coefficient α in the above equation (1) for calculating the allowable upper limit value V _lim of the relative speed is changed. That is, in the present embodiment, as shown in the graph on the left side of FIG. 13, the correction coefficient α = 1 in the normal state, and the allowable upper limit value V _lim of the relative speed is the clearance in the lateral direction with the surrounding vehicle 3. As X increases, it increases in a quadratic function with a predetermined slope. On the other hand, when it is estimated that the surrounding vehicle 3 ahead is going to change the lane, the correction coefficient α is changed to 0.8, and the clearance X of the clearance X is changed as shown in the graph on the right side of FIG. The slope at which the allowable upper limit value V _lim of the relative speed increases as a quadratic function with respect to the increase is changed to a gentle slope. In the present embodiment, when the rotation angle of the steering wheel of the surrounding vehicle 3 is less than a predetermined value and when the operation information of the surrounding vehicle is not obtained via the inter-vehicle communication system 26, “normal time” is assumed. Processed, the correction factor defaults to α = 1.

  After setting the value of the correction coefficient α in step S25, the processing in the ECU 10 proceeds to step S26. In step S26, the speed limit distribution 40 is set based on the set correction coefficients α and β (the value of β remains the default), and one process of the flowchart shown in FIG. The processing in returns to the flowchart shown in FIG.

  When the correction coefficient α is changed to a small value in step S25, the speed limit distribution 40 set in step S26 changes from that shown on the left side of FIG. 14 to that shown on the right side. That is, the speed limit distribution 40 extends from the normal time (α = 1) shown on the left side of FIG. 14 to the lateral direction of the surrounding vehicle 3 (direction perpendicular to the traveling direction) as shown on the right side of FIG. Will be changed. As a result, when it is estimated that the surrounding vehicle 3 traveling in front of the host vehicle 1 changes lanes, the lateral speed limit in the speed limit distribution 4 is reduced. Even when the surrounding vehicle 3 is estimated to change lanes, since the value of the correction coefficient β in the equation (2) is not changed, the length of the speed limit distribution 40 in the vertical direction (travel direction of the host vehicle), normal time Is the same.

  In the example shown in FIG. 14, when the host vehicle 1 is traveling behind the surrounding vehicle 3 and trying to pass the surrounding vehicle 3 ahead, the host vehicle 1 travels while accelerating in the normal time shown on the left side. By changing the lane to the right side, it is possible to avoid exceeding the allowable relative speed with the surrounding vehicle 3. However, when the own vehicle 1 starts changing lanes at the same time as the surrounding vehicle 3 also starts changing lanes, the own vehicle 1 approaches the surrounding vehicle 3 that has changed lanes, giving the driver anxiety. It is done. On the other hand, when it is detected that the surrounding vehicle 3 is changing the lane and the correction coefficient α is changed to 0.8, the speed limit distribution 40 is expanded in the horizontal direction as shown on the right side of FIG. . As a result, the target travel route (corrected travel route) of the host vehicle 1 trying to pass the surrounding vehicle 3 is included in the speed limit distribution 40 around the surrounding vehicle 3. Route setting is avoided.

  Thus, in this embodiment, when it is estimated that the surrounding vehicle 3 ahead changes the lane, the speed limit in the lateral direction in the speed limit distribution is reduced, so that the host vehicle 1 overtakes the surrounding vehicle 3. Setting of the travel route is restricted, and accidental approach between the host vehicle 1 and the surrounding vehicle 3 can be avoided. For this reason, when the own vehicle 1 tries to change lanes almost simultaneously with the surrounding vehicle 3 in front, the anxiety given to the driver can be reduced.

  According to the vehicle control apparatus of the embodiment of the present invention, the speed distribution setting unit 10d estimates a change in the traveling behavior of the surrounding vehicle 3 based on the operation information received by the inter-vehicle communication system 26, and the restriction is made accordingly. A velocity distribution 40 is set. For this reason, the driver of the surrounding vehicle 3 performs acceleration / deceleration and steering operations, and the change in the traveling behavior of the surrounding vehicle 3 is performed earlier than this operation appears after the operation appears in the traveling behavior of the surrounding vehicle 3. It is possible to set the speed limit distribution 40 according to the above, and it is possible to avoid sudden deceleration and steering.

  Further, according to the vehicle control device of the present embodiment, a plurality of speed limit distributions 40 (FIG. 6) are set according to the distance from the surrounding vehicle 3, so that the distance (X or Y) from the surrounding vehicle 3 is set. A speed limit can be set step by step. For this reason, it is possible to set a smooth travel route that satisfies the speed limit distribution 40, and the ride comfort of the host vehicle 1 can be improved.

  Furthermore, according to the vehicle control apparatus of the present embodiment, when it is estimated that the surrounding vehicle 3 ahead is decelerated by a predetermined amount or more (steps S22 → S23 in FIG. 10), the travel direction restriction in the speed limit distribution 40 is achieved. Since the speed is reduced (FIG. 12), in order to satisfy the speed limit distribution 40, deceleration of the host vehicle 1 is started early. For this reason, braking or the like for satisfying the speed limit distribution 40 can be executed gently, and the ride comfort of the host vehicle can be improved.

  Moreover, according to the vehicle control apparatus of this embodiment, when it is estimated that the surrounding vehicle ahead changes the lane, the speed limit in the lateral direction in the speed limit distribution 40 is reduced (FIG. 14). Since the speed limit in the lateral direction is reduced in this way, it becomes difficult to set a driving route that avoids the surrounding vehicle 3 in front of which the lane is to be changed, and the overtaking by driving support of the host vehicle 1 is restricted. Can do.

As mentioned above, although preferable embodiment of this invention was described, a various change can be added to embodiment mentioned above. In particular, in the above-described embodiment of the present invention, when it is estimated that the surrounding vehicle 3 ahead is decelerated by a predetermined amount or more, the correction coefficient β is decreased stepwise from 1 to 0.8 (see FIG. As a modification, 10 step S23) can linearly lower the correction coefficient β as shown in FIG. In other words, in this modification, the correction coefficient β = 1 in the normal state, and when the deceleration of the surrounding vehicle 3 becomes larger than the predetermined value a ₁ (when the vehicle decelerates more rapidly than the predetermined deceleration a ₁ ), the correction is performed. The coefficient β is linearly changed to a small value. Preferably, when the peripheral vehicle 3 is suddenly decelerated at a deceleration close to the vehicle limit, the correction coefficient β is reduced to about 0.5.

Further, in the above-described embodiment of the present invention, the speed limit distribution 40 is expanded laterally on both sides of the peripheral vehicle 3 when the front peripheral vehicle 3 is about to change lanes. On the other hand, as a modification, as shown in FIG. 16, the present invention can be configured such that the speed limit distribution 40 is expanded only on the side where the surrounding vehicle 3 is about to change lanes. That is, in the example shown in FIG. 16, when it is estimated that the surrounding vehicle 3 traveling in front of the host vehicle 1 changes lanes in the right direction, which is the first direction, the speed limit only in the right direction in the speed limit distribution 40. (The value of the correction coefficient α is decreased only when the allowable upper limit value V _lim of the right relative speed is calculated.) Thereby, unnecessary expansion of the speed limit distribution 40 is avoided, and a wide range of target travel routes (corrected travel routes) can be set.

  Further, in the above-described embodiment of the present invention, it is determined whether or not sudden braking has been applied in step S22 of the flowchart shown in FIG. 10, and if sudden braking has been applied, step S23 is executed and the correction coefficient is calculated. Only β was changed. As a modification, the present invention can also be configured to determine whether or not the surrounding vehicle 3 is changing lanes (the same processing as step S24 in FIG. 10) even when sudden braking is applied. . When sudden braking is applied and the lane is changed, both the correction coefficients α and β are changed to small values.

1 Vehicle 10 Vehicle Control Operation Unit (ECU)
DESCRIPTION OF SYMBOLS 10a Input processing part 10b Surrounding vehicle detection part 10c Target travel route calculation part 10d Speed distribution setting part 10e Control part 21 Camera 22 Millimeter wave radar 23 Vehicle speed sensor 24 Positioning system 25 Navigation system 26 Inter-vehicle communication system (operation information receiving part)
31 Engine control system 32 Brake control system 33 Steering control system 40 Speed limit distribution 100 Vehicle control device

Claims (5)

A vehicle control device for controlling the traveling of a vehicle,
A surrounding vehicle detector that detects surrounding vehicles traveling around the host vehicle;
An operation information receiving unit that receives operation information related to acceleration / deceleration and / or steering by a driver of the surrounding vehicle from the surrounding vehicle detected by the surrounding vehicle detection unit;
A speed distribution setting unit that sets a speed limit distribution that defines an upper limit value of an allowable relative speed around the surrounding vehicle detected by the surrounding vehicle detection unit;
A control unit that controls the speed and / or steering of the host vehicle so as to satisfy the speed limit distribution set by the speed distribution setting unit,
The speed distribution setting unit estimates a change in driving behavior of a surrounding vehicle based on the operation information received by the operation information receiving unit, and sets a speed limit distribution according to the change. .   The vehicle control device according to claim 1, wherein the speed distribution setting unit sets a plurality of speed limit distributions according to a distance from the surrounding vehicle.   The speed distribution setting unit, when it is estimated that a surrounding vehicle traveling in front of the host vehicle decelerates a predetermined amount or more based on the operation information received by the operation information receiving unit, The vehicle control device according to claim 1, wherein the speed limit in the traveling direction is reduced.   The speed distribution setting unit, when it is estimated based on the operation information received by the operation information receiving unit that the surrounding vehicle traveling in front of the host vehicle changes the lane in the first direction, the speed limit The vehicle control device according to claim 1, wherein a speed limit in at least the first direction in the distribution is reduced. A vehicle control method for controlling travel of a vehicle,
An operation information receiving step of detecting a surrounding vehicle traveling around the host vehicle and receiving operation information on acceleration / deceleration and / or steering by a driver of the surrounding vehicle from the detected surrounding vehicle;
A speed distribution setting step for setting a speed limit distribution that defines an upper limit value of an allowable relative speed around the surrounding vehicle detected in the surrounding vehicle detection step;
A control step of controlling the speed and / or steering of the host vehicle so as to satisfy the speed limit distribution set in the speed distribution setting step,
In the speed distribution setting step, a change in driving behavior of a surrounding vehicle is estimated based on the operation information received in the operation information receiving step, and a speed limit distribution is set in accordance with the change. Control method.

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