JP7095201B2 - Automatic braking device - Google Patents

Description

The present invention relates to an automatic braking device that determines the possibility of a collision between a vehicle and an obstacle and automatically brakes.

Conventionally, there is known an automatic braking device that determines the possibility of a collision between a detected obstacle and the own vehicle and automatically activates the brake when there is a possibility of a collision. The automatic braking device is configured to regulate automatic braking when certain conditions are met, in order to prevent unnecessary braking. For example, Patent Document 1 describes an automatic braking device that regulates automatic braking when the detected obstacle is an oncoming vehicle.

The automatic braking device determines that the obstacle is an oncoming vehicle when the relative speed between the own vehicle and the obstacle is larger than the own vehicle speed, that is, when (relative speed-own vehicle speed)> 0. , Regulate automatic braking.

Japanese Unexamined Patent Publication No. 5-24517

However, the detected value of the relative velocity includes an error. Therefore, even though the obstacle is actually a preceding vehicle traveling in the same lane, it may be determined that the vehicle is an oncoming vehicle due to the error and automatic braking may be restricted. In particular, the greater the distance to the obstacle and the greater the vehicle speed, the greater the error. Therefore, when the distance to the obstacle is large and the vehicle speed is high, there is a high possibility that the vehicle is erroneously determined to be an oncoming vehicle.

The present invention has been devised under the above circumstances, and an object of the present invention is to provide an automatic braking device capable of suppressing erroneous determination as an oncoming vehicle.

In order to solve the above problems, the following technical means are taken in the present invention.

The automatic braking device provided by the present invention is an automatic braking device that determines the possibility of collision with an obstacle and performs automatic braking, and is a distance between the obstacle and the vehicle and the obstacle. An oncoming vehicle that determines whether or not the obstacle is an oncoming vehicle by comparing an information acquisition means for acquiring the relative speed and the own vehicle speed, a calculated value based on the relative speed and the own vehicle speed, and a determination threshold value. When the determination means is provided with a threshold setting means for setting the determination threshold according to the distance to the obstacle or the own vehicle speed, and the oncoming vehicle determination means determines that the obstacle is an oncoming vehicle. Is characterized by regulating automatic braking.

According to the present invention, a determination threshold value is set according to the distance to the obstacle or the own vehicle speed, and whether or not the obstacle is an oncoming vehicle by comparing the calculated value based on the relative speed and the own vehicle speed with the determination threshold value. Is judged. Even if the detected value of the relative speed includes an error that changes depending on the distance to the obstacle or the vehicle speed, an appropriate value according to the distance to the obstacle or the vehicle speed is used as the judgment threshold value, so that the oncoming vehicle It is possible to suppress the erroneous judgment that it is.

Other features and advantages of the invention will be more apparent by the detailed description given below with reference to the accompanying drawings.

It is a block diagram which shows the structure of the vehicle to which the automatic braking device which concerns on 1st Embodiment is applied. It is a figure which shows the situation when a car enters a turning road from a straight road. It is a figure which shows an example of the judgment threshold table. This is an example of a flowchart for explaining the automatic braking control process performed by the automatic braking ECU.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of a vehicle 1 to which the automatic braking device according to the first embodiment is applied. As shown in FIG. 1, the vehicle 1 includes an automatic braking ECU (Electric Control Unit) 2, a camera 3, an image processing unit 4, a vehicle speed sensor 51, a display device 6, an alarm device 7, and a braking device 8. Although the vehicle 1 has other configurations, the description is omitted in FIG.

The camera 3 is a photographing device that captures an image in front of the vehicle 1, and is provided with an image pickup device such as a CCD or CMOS, and captures a predetermined imaging region at a predetermined frame rate. The camera 3 is attached to the front portion of the vehicle 1 near the center in the vehicle width direction. The camera 3 is a stereo camera and has two lenses separated in the vehicle width direction, and an image input through each lens is acquired as image data by an image pickup device. That is, the camera 3 acquires a pair of image data. The image data taken by the camera 3 is output to the image processing unit 4.

The image processing unit 4 is a processing unit that performs image processing, and is realized by a microcomputer. The image processing unit 4 performs image processing on a pair of image data input from the camera 3. The image processing unit 4 includes an obstacle detection unit 41, a distance calculation unit 42, and a relative speed calculation unit 43.

The obstacle detection unit 41 detects an obstacle in front of the vehicle 1 based on a pair of image data input from the camera 3. The method of detecting an obstacle is not limited. The distance calculation unit 42 detects the distance between the obstacle detected by the obstacle detection unit 41 and the own vehicle (vehicle 1). The distance calculation unit 42 detects the deviation amount of the pixels at the corresponding positions of the pair of images from the pair of image data input from the camera 3, and calculates the distance from the deviation amount based on the principle of triangulation. The method of calculating the distance is not limited. The relative speed calculation unit 43 calculates the relative speed between the obstacle detected by the obstacle detection unit 41 and the own vehicle. The relative speed calculation unit 43 calculates the relative speed based on the change in the distance between the obstacle and the own vehicle calculated by the distance calculation unit 42. In the present embodiment, the relative speed of the obstacle to the own vehicle is calculated as a positive value when traveling in the traveling direction of the own vehicle. That is, when the obstacle moves toward the own vehicle, the relative speed becomes a negative value. The method of defining and calculating the relative velocity is not limited. The image processing unit 4 associates the detected obstacle information, the distance with the obstacle, and the relative speed, and outputs the information to the automatic braking ECU 2.

The vehicle speed sensor 51 is a sensor that detects the vehicle speed of the vehicle 1. The vehicle speed sensor 51 generates a pulse signal synchronized with the rotation of the wheel and outputs the pulse signal to the automatic braking ECU 2. The automatic braking ECU 2 calculates the vehicle speed of the vehicle 1 (hereinafter referred to as "own vehicle speed") based on the frequency of the pulse signal input from the vehicle speed sensor 51. The vehicle speed sensor 51 may calculate the own vehicle speed and output it to the automatic braking ECU 2.

The display device 6 is composed of, for example, an LCD (liquid crystal display device) and is installed in the center console portion of the vehicle 1. The display device 6 is not limited to the LCD, and may be an organic EL display, a plasma display, or the like. Further, the installation position is not limited to the center console portion, and may be within a range that can be seen by the driver. The display device 6 displays various types of displays, and in the present embodiment, the display device 6 displays a display for notifying the driver when performing automatic braking. The display device 6 may also be used as a display for a navigation system or the like.

The alarm device 7 transmits information by voice and gives a warning by a buzzer to the driver. In the present embodiment, when automatic braking is performed, voice guidance is provided to notify the driver of the fact. The alarm device 7 may also be used as a voice system such as a navigation system.

The braking device 8 brakes the vehicle 1. The braking device 8 operates a disc brake or a drum brake according to the operation of the brake pedal by the driver to generate a braking force. Further, the braking device 8 generates a braking force according to an electric signal input from the automatic braking ECU 2.

The automatic braking ECU 2 is an electronic control unit for performing automatic braking, and is realized by a microcomputer provided with a CPU and a memory. The automatic braking ECU 2 determines the possibility of collision with an obstacle based on the information input from various sensors such as the image processing unit 4 and the vehicle speed sensor 51, and when there is a possibility of collision, the braking device 8 is used. Let automatic braking be performed. Further, in this case, the automatic braking ECU 2 causes the display device 6 to display that automatic braking is to be performed, and causes the alarm device 7 to perform voice guidance for performing automatic braking. The automatic braking ECU 2 may display the display device 6 to indicate that the automatic braking is to be performed soon before the braking device 8 is to perform the automatic braking, and may inform the alarm device 7 by voice.

Further, the automatic braking ECU 2 determines whether or not the obstacle is an oncoming vehicle. When the automatic braking ECU 2 determines that the vehicle is an oncoming vehicle, the automatic braking ECU 2 regulates the automatic braking so as not to perform the automatic braking. If the obstacle is an oncoming vehicle, it is in a different lane and the possibility of a collision is low. Therefore, it is determined that it is not necessary to perform automatic braking. When the vehicle 1 is traveling on a straight road, the oncoming vehicle is not located in front of the vehicle and is not recognized as an obstacle. However, when the vehicle 1 enters the turning road from the straight road, the oncoming vehicle may be located in front of the vehicle 1. In this case, the oncoming vehicle is recognized as a preceding vehicle traveling in the same lane, and unnecessary automatic braking is performed. In order to prevent this, the automatic braking ECU 2 determines whether or not the obstacle is an oncoming vehicle, and if it is determined that the obstacle is an oncoming vehicle, the automatic braking ECU 2 regulates automatic braking.

FIG. 2 shows a situation when the vehicle 1 enters a turning road from a straight road. The car 11 is a preceding vehicle traveling in the same lane as the car 1. The vehicle 12 is an oncoming vehicle traveling in the oncoming lane. The solid arrows attached to the car 1, the car 11, and the car 12 indicate the direction of travel. The automatic braking ECU 2 of the vehicle 1 recognizes the vehicle 11 located in front of the vehicle 11 as an obstacle. Further, since the car 12 is also located in front of the car 1, the automatic braking ECU 2 of the car 1 recognizes that the car 12 is also an obstacle.

When the automatic braking ECU 2 recognizes an obstacle, it determines whether or not there is a possibility of colliding with the obstacle. When the automatic braking ECU 2 determines that there is a possibility of collision with an obstacle, the automatic braking ECU 2 determines whether or not the obstacle is an oncoming vehicle based on the traveling direction of the obstacle. Then, the automatic braking ECU 2 performs automatic braking when it is determined that the obstacle is not an oncoming vehicle, and does not perform automatic braking when it is determined that the obstacle is an oncoming vehicle. For example, in the example of FIG. 2, the traveling direction of the vehicle 11 coincides with the traveling direction of the vehicle 1. Therefore, when the automatic braking ECU 2 detects the vehicle 11 and determines that there is a possibility of collision, the automatic braking ECU 2 determines that the vehicle 11 is not an oncoming vehicle and performs automatic braking. On the other hand, the traveling direction of the vehicle 12 is opposite to the traveling direction of the vehicle 1. Therefore, even if the automatic braking ECU 2 detects the vehicle 12 and determines that there is a possibility of collision, the automatic braking ECU 2 determines that the vehicle 12 is an oncoming vehicle and regulates automatic braking. The combination of the automatic braking ECU 2 and the braking device 8 corresponds to the "automatic braking device" of the present invention.

The automatic braking ECU 2 includes a collision possibility determination unit 21, an oncoming vehicle determination unit 22, an automatic braking regulation unit 23, and a storage unit 24 as functional blocks.

The storage unit 24 stores various data. In this embodiment, the collision avoidance threshold table and the determination threshold table, which will be described later, are stored.

The collision possibility determination unit 21 is a functional block for determining the possibility of collision with an obstacle. The collision possibility determination unit 21 determines whether or not the vehicle 1 may collide with the obstacle based on the information regarding the obstacle input from the image processing unit 4. Specifically, the collision possibility determination unit 21 reads out the collision avoidance threshold value corresponding to the input relative velocity from the storage unit 24. The collision avoidance threshold value is a threshold value for determining whether or not the distance is such that a collision with an obstacle can be avoided by braking or steering by the driver. The collision avoidance threshold depends on the magnitude of the relative velocity, and increases as the absolute value of the relative velocity increases. The storage unit 24 stores a collision avoidance threshold table showing the correspondence between the absolute value of the relative velocity and the collision avoidance threshold. The collision possibility determination unit 21 compares the input distance to the obstacle and the read collision avoidance threshold value. Then, when the distance is equal to or less than the collision avoidance threshold value, it is determined that there is a possibility of collision.

The oncoming vehicle determination unit 22 is a functional block that determines whether or not the obstacle is an oncoming vehicle. The oncoming vehicle determination unit 22 is based on the information about the obstacle input from the image processing unit 4 and the own vehicle speed (or the input own vehicle speed) calculated based on the pulse signal input from the vehicle speed sensor 51. It is determined whether or not the vehicle 1 is an oncoming vehicle. Specifically, the oncoming vehicle determination unit 22 adds the own vehicle speed and the input relative speed to calculate the speed of the obstacle (more accurately, the traveling direction component of the vehicle 1 of the obstacle speed). Since the relative speed in this embodiment is the relative speed of the obstacle to the own vehicle, the speed of the obstacle can be theoretically calculated by adding the own vehicle speed and the relative speed. However, the relative speed calculated by the image processing unit 4 includes an error. Therefore, if it is determined whether or not the vehicle is an oncoming vehicle based on the positive or negative of the calculated obstacle speed using the calculated relative speed of the obstacle, an erroneous judgment may be made.

In addition, the error included in the relative speed differs depending on the distance to the obstacle and the vehicle speed. The greater the distance to the obstacle, the lower the accuracy of the distance calculated by the distance calculation unit 42, and therefore the larger the error included in the calculated distance. The relative speed calculation unit 43 calculates the relative speed based on the distance calculated by the distance calculation unit 42. Therefore, the error included in the relative velocity calculated by the relative velocity calculation unit 43 also increases as the actual distance from the obstacle increases. Further, the higher the vehicle speed, the worse the accuracy of the distance calculated by the distance calculation unit 42. Therefore, the relative speed calculated by the relative speed calculation unit 43 increases as the own vehicle speed increases. The oncoming vehicle determination unit 22 determines whether or not the vehicle is an oncoming vehicle in consideration of the relative speed error that differs depending on the distance to the obstacle and the own vehicle speed.

The oncoming vehicle determination unit 22 includes an obstacle speed calculation unit 221, a threshold value setting unit 222, and a determination unit 223.

The obstacle speed calculation unit 221 calculates the speed of the obstacle by adding the relative speed of the obstacle input from the image processing unit 4 and the own vehicle speed. The obstacle speed calculation unit 221 outputs the calculated speed of the obstacle to the determination unit 223.

For example, in the example of FIG. 2, it was calculated that the own vehicle speed of the vehicle 1 is 30 km / h and the relative speed of the vehicle 12 is -50 km / h (the vehicle 12 approaches the vehicle 1 at 50 km / h). In this case, the obstacle speed calculation unit 221 calculates the speed of the vehicle 12 (a component in the traveling direction of the vehicle 1) as −20 km / h. Further, when the relative speed of the vehicle 11 is calculated to be -25 km / h (the vehicle 11 approaches the vehicle 1 at 25 km / h), the obstacle speed calculation unit 221 determines the speed of the vehicle 11 (vehicle 1). The component in the traveling direction of) is calculated as 5 km / h. However, when the relative speed is calculated to be −35 km / h (the car 11 approaches the car 1 at 35 km / h) due to the detection error, the obstacle speed calculation unit 221 uses the speed of the car 11 (the car 1). The component in the traveling direction of) is calculated as −5 km / h. In this case, if it is determined whether or not the vehicle is an oncoming vehicle based on the positive or negative speed of the obstacle, it is an erroneous determination.

The threshold value setting unit 222 sets a determination threshold value for determining whether or not the vehicle is an oncoming vehicle. The threshold value setting unit 222 is based on the distance to the obstacle input from the image processing unit 4 and the own vehicle speed (or the input own vehicle speed) calculated based on the pulse signal input from the vehicle speed sensor 51. Set the judgment threshold. Specifically, the threshold value setting unit 222 reads out the determination threshold value corresponding to the distance to the obstacle and the own vehicle speed from the storage unit 24. The determination threshold is a threshold for determining whether or not the obstacle is an oncoming vehicle, and is compared with the calculated speed of the obstacle. The judgment threshold value differs depending on the distance to the obstacle, and the larger the distance, the smaller the judgment threshold (the larger the absolute value). Further, the determination threshold value differs depending on the own vehicle speed, and becomes smaller (the absolute value becomes larger) as the own vehicle speed increases. The storage unit 24 stores a determination threshold value table showing the correspondence between the distance to the obstacle and the own vehicle speed and the determination threshold value.

FIG. 3 is a diagram showing an example of a determination threshold table. In the determination threshold table shown in FIG. 3, the distance D from the obstacle is divided into 10 m intervals from 0 m to 50 m, and the vehicle speed V ₁ is divided into 10 km / h from 0 km / h to 60 km / h. , The determination threshold value corresponding to each is stored. In FIG. 3, when the distance D is 0 ≦ D ≦ 10 and the own vehicle speed V ₁ is 0 ≦ V ₁ ≦ 10, there is almost no error, so the minimum “0” is stored as the determination threshold value. Further, when the distance D is 40 <D ≦ 50 and the own vehicle speed V ₁ is 50 <V ₁ ≦ 60, the error becomes maximum, so “-20” is stored as the determination threshold value. Further, when the distance D is 20 <D ≦ 30 and the own vehicle speed V ₁ is 20 <V ₁ ≦ 30, “-10” is stored as the determination threshold value. Further, when the distance D is 40 <D ≦ 50 and the own vehicle speed V ₁ is 20 <V ₁ ≦ 30, “-12” is stored as the determination threshold value. Numerical values are omitted in the other columns, but the larger the distance D is if the vehicle speed V ₁ is within the same range, and the larger the vehicle speed V ₁ is if the distance D is within the same range. , Small values are stored. It should be noted that each determination threshold value shown in FIG. 3 is an example, and is not limited to this, and is appropriately set by verifying an actual error.

The detected value of the relative velocity may be larger or smaller than the actual value due to the detection error. If it is erroneously determined to be an oncoming vehicle even though it is not an oncoming vehicle and automatic braking is regulated, the risk of collision increases. On the other hand, if it is erroneously determined that the vehicle is not an oncoming vehicle even though it is an oncoming vehicle and automatic braking is not regulated, unnecessary automatic braking is performed. The problem is greater when it is erroneously determined that it is an oncoming vehicle than when it is erroneously determined that it is not an oncoming vehicle. Therefore, in order to prevent the vehicle from being erroneously determined to be an oncoming vehicle, the determination threshold value is set to a value at which the vehicle is not erroneously determined to be an oncoming vehicle even when the relative speed is detected to be the smallest due to an error. ..

Note that FIG. 3 shows a determination threshold table when the distance D is 50 m or less and the vehicle speed V ₁ is 60 km / h or less. However, the distance D and the vehicle speed when determining an oncoming vehicle are shown. Depending on V ₁ , it may be a table with a wider range or a table with a narrower range. Further, in FIG. 3, the distance D is divided every 10 m, but it may be divided more finely (for example, every 5 m) or larger (for example, 30 m or less and larger than 30 m). Further, in FIG. 3, the own vehicle speed V ₁ is divided by 10 km / h, but it may be divided more finely (for example, every 5 km / h) or larger (for example, 30 km / h or less and 30 km / h). It may be divided into larger than h).

The threshold value setting unit 222 reads the determination threshold value corresponding to the distance to the obstacle and the own vehicle speed from the determination threshold value table and outputs the determination threshold value to the determination unit 223. For example, when the determination threshold table of FIG. 3 is stored, when the distance D is 30 m and the own vehicle speed V ₁ is 30 km / h, the threshold setting unit 222 reads "-10" as the determination threshold and determines. Output to 223.

The determination unit 223 compares the speed of the obstacle input from the obstacle speed calculation unit 221 with the determination threshold value input from the threshold value setting unit 222, and the traveling direction of the obstacle matches the traveling direction of the vehicle 1. Determine whether or not to do so. When the speed of the obstacle is equal to or less than the determination threshold value, the determination unit 223 determines that the traveling direction of the obstacle does not match the traveling direction of the vehicle 1 and is in the opposite direction. As a result, the oncoming vehicle determination unit 22 determines that the obstacle is an oncoming vehicle. On the other hand, when the speed of the obstacle is larger than the determination threshold value, the determination unit 223 determines that the traveling direction of the obstacle matches the traveling direction of the vehicle 1. As a result, the oncoming vehicle determination unit 22 determines that the obstacle is the preceding vehicle and is not the oncoming vehicle.

For example, in the example of FIG. 2, the own vehicle speed of the vehicle 1 is 30 km / h, and the actual speed of the vehicle 11 (the component in the traveling direction of the vehicle 1) is 5 km / h, but the relative speed is −35 km due to a detection error. When calculated as / h, the obstacle speed calculation unit 221 calculates the speed of the vehicle 11 (a component in the traveling direction of the vehicle 1) as −5 km / h. The threshold value setting unit 222 sets a determination threshold value (-10) assuming an error based on the determination threshold value table shown in FIG. 3, the own vehicle speed (30 km / h) of the vehicle 1 and the distance (30 m) from the vehicle 11. Set. In this case, since the speed (-5) of the vehicle 11 is larger than the determination threshold value (-10), the determination unit 223 determines that the traveling direction of the vehicle 11 coincides with the traveling direction of the vehicle 1. As a result, the oncoming vehicle determination unit 22 determines that the vehicle 11 is the preceding vehicle and is not an oncoming vehicle.

When the relative speed of the vehicle 12 is calculated to be −50 km / h, the obstacle speed calculation unit 221 calculates the speed of the vehicle 12 (a component in the traveling direction of the vehicle 1) to be −20 km / h. The threshold value setting unit 222 sets a determination threshold value (-12) assuming an error based on the determination threshold value table shown in FIG. 3, the own vehicle speed (30 km / h) of the vehicle 1 and the distance (50 m) from the vehicle 12. Set. In this case, since the speed (-20) of the vehicle 12 is equal to or less than the determination threshold value (-12), the determination unit 223 determines that the traveling direction of the vehicle 12 does not match the traveling direction of the vehicle 1 and is in the opposite direction. As a result, the oncoming vehicle determination unit 22 determines that the vehicle 12 is an oncoming vehicle. If the relative speed of the vehicle 12 is calculated to be larger than −42 km / h due to a detection error, the oncoming vehicle determination unit 22 erroneously determines that the vehicle 12 is not an oncoming vehicle. However, it is rare that the error becomes so large, and even if it is judged incorrectly, only unnecessary automatic braking is performed, and there is no danger.

The automatic braking regulation unit 23 is a functional block that regulates automatic braking. The automatic braking regulation unit 23 regulates automatic braking according to the determination result of the oncoming vehicle determination unit 22. That is, the automatic braking regulation unit 23 does not regulate automatic braking when the oncoming vehicle determination unit 22 determines that the vehicle is not an oncoming vehicle, and regulates automatic braking when the oncoming vehicle determination unit 22 determines that the vehicle is an oncoming vehicle. I do. The automatic braking regulation unit 23 regulates automatic braking depending on other conditions. For example, automatic braking is regulated even when the driver operates the steering wheel or the brake, or when the vehicle speed is equal to or higher than a predetermined speed. In the present embodiment, the description of the determination of these other conditions is omitted.

FIG. 4 is an example of a flowchart for explaining the automatic braking control process performed by the automatic braking ECU 2. The automatic braking control process is performed at a predetermined timing (for example, every 0.1 seconds).

First, various information is acquired (S1). Specifically, the automatic braking ECU 2 acquires information on obstacles, a distance to the obstacles, and a relative speed from the image processing unit 4. Further, the automatic braking ECU 2 obtains by inputting a pulse signal from the vehicle speed sensor 51 and calculating the own vehicle speed based on the pulse signal.

Next, the collision possibility determination unit 21 determines whether or not there is a possibility of collision with an obstacle (S2). Specifically, the collision possibility determination unit 21 reads out the collision avoidance threshold value corresponding to the acquired relative velocity from the collision avoidance threshold value table stored in the storage unit 24. Then, the collision possibility determination unit 21 determines that there is a possibility of collision when the acquired distance to the obstacle is equal to or less than the read collision avoidance threshold value.

When it is determined that there is no possibility of collision (S2: NO), the automatic braking control process is terminated. On the other hand, when it is determined that there is a possibility of collision (S2: YES), the obstacle speed calculation unit 221 calculates the speed of the obstacle (component in the traveling direction of the vehicle 1) V ₂ (S3). Specifically, the obstacle speed calculation unit 221 calculates the speed V ₂ of the obstacle by adding the relative speed of the obstacle and the own vehicle speed. Next, the threshold value setting unit 222 acquires the determination threshold value Vth (S4). Specifically, the threshold value setting unit 222 acquires the determination threshold value Vth corresponding to the distance to the obstacle and the own vehicle speed by reading from the determination threshold value table (see FIG. 3) stored in the storage unit 24.

Next, the determination unit 223 compares the speed V ₂ of the obstacle with the determination threshold value Vth (S5). When the speed V ₂ of the obstacle is equal to or less than the determination threshold value Vth (S5: YES), the determination unit 223 determines that the traveling direction of the obstacle is opposite to the traveling direction of the vehicle 1. In this case, the automatic braking regulation unit 23 regulates the automatic braking, and the automatic braking control process is terminated. On the other hand, when the speed V ₂ of the obstacle is larger than the determination threshold value Vth (S5: NO), the determination unit 223 determines that the traveling direction of the obstacle matches the traveling direction of the vehicle 1. In this case, since the automatic braking regulation unit 23 does not regulate the automatic braking, the automatic braking is performed (S6), and the automatic braking control process is terminated. Specifically, the automatic braking ECU 2 causes the braking device 8 to perform automatic braking.

When the automatic braking is performed in step S6, the vehicle 1 is braked. Therefore, at the timing of the next automatic braking control process, the absolute value of the relative speed of the obstacle becomes small and the distance to the obstacle becomes small. become longer. Nevertheless, if it is determined in step S2 that there is a possibility of collision (S2: YES), the automatic braking (step S6) is continued. On the other hand, when it is determined in step S2 that there is no possibility of collision (S2: NO), the automatic braking is canceled.

If a plurality of obstacles are detected from the information acquired in step S1, the processing after step S2 is performed for each obstacle. The automatic braking control process performed by the automatic braking ECU 2 is not limited to the flowchart shown in FIG.

According to the present embodiment, the obstacle speed calculation unit 221 adds the relative speed of the obstacle and the own vehicle speed to calculate the speed of the obstacle. When the speed of the obstacle is equal to or less than the determination threshold value, the determination unit 223 determines that the traveling direction of the obstacle is opposite to the traveling direction of the vehicle 1. As a result, the oncoming vehicle determination unit 22 determines that the obstacle is an oncoming vehicle. In this case, since automatic braking is regulated, unnecessary automatic braking for oncoming vehicles can be suppressed. Further, the threshold value setting unit 222 sets the determination threshold value based on the distance to the obstacle and the own vehicle speed. The determination threshold value is stored in advance in the storage unit 24 so that the larger the distance to the obstacle, the smaller the determination threshold value, and the larger the vehicle speed, the smaller the determination threshold value. Even if the error that changes depending on the distance to the obstacle and the own vehicle speed is included in the detected value of the relative speed, the distance to the obstacle and the own vehicle speed are used as the judgment threshold value for determining whether or not the vehicle is an oncoming vehicle. Since an appropriate value corresponding to the value is used, the oncoming vehicle determination unit 22 can prevent the oncoming vehicle from erroneously determining that the vehicle is an oncoming vehicle even though it is not an oncoming vehicle.

In the present embodiment, the case where the threshold value setting unit 222 sets the determination threshold value based on both the distance to the obstacle and the own vehicle speed has been described, but the present invention is not limited to this. The threshold value setting unit 222 may set a determination threshold value based on the own vehicle speed V ₁ regardless of the distance D, for example, using the determination threshold value table shown in FIG. 3 (b). Further, for example, using the determination threshold value table shown in FIG. 3C, the determination threshold value based _on the distance D may be set regardless of the own vehicle speed V1. That is, the threshold value setting unit 222 may set a determination threshold value based on at least _one of the distance D and the own vehicle speed V1. Further, when the determination threshold table shown in FIGS. 3 (b) and 3 (c) is used, the threshold setting unit 222 may calculate and use the determination threshold by linear interpolation according to the own vehicle speed V ₁ or the distance D. ..

In the present embodiment, the case where the threshold value setting unit 222 reads out and sets the determination threshold value stored in the storage unit 24 has been described, but the present invention is not limited to this. For example, the threshold value setting unit 222 may calculate the determination threshold value based on a predetermined calculation formula. For example, the arithmetic expression may be a simple arithmetic expression such as the determination threshold Vth = a · V ₁ + b · D (a and b are predetermined coefficients), or may be a more complicated arithmetic expression. In this case, since it is not necessary to store the determination threshold table, the storage capacity of the storage unit 24 can be suppressed.

In the present embodiment, the case where the camera 3 and the image processing unit 4 detect the distance to the obstacle and the relative speed of the obstacle has been described, but the present invention is not limited thereto. Other sensors, such as laser radar and sonar, may detect the distance to the obstacle and the relative velocity of the obstacle. However, if the detection principle of distance and relative velocity is different, the error included in the detected distance and relative velocity is also different. In the present embodiment, when the detection principle of the distance and the relative speed and the detection sensor are changed, the oncoming vehicle determination unit is simply changed by changing the determination threshold table stored in the storage unit 24 to one corresponding to the detection principle and the detection sensor. 22 can make an appropriate determination. The distance to the obstacle and the relative speed of the obstacle may be calculated based on the detection result by the camera 3 and the detection result by these sensors.

The automatic braking device according to the present invention is not limited to the above-described embodiment. The specific configuration of each part of the automatic braking device according to the present invention can be freely redesigned.

1 car 2 automatic braking ECU
21 Collision possibility judgment unit 22 Oncoming vehicle judgment unit 221 Obstacle speed calculation unit 222 Threshold setting unit 223 Judgment unit 23 Automatic braking regulation unit 24 Storage unit 3 Camera 4 Image processing unit 41 Obstacle detection unit 42 Distance calculation unit 43 Relative velocity Calculation unit 51 Vehicle speed sensor 6 Display device 7 Alarm device 8 Braking device 11, 12 Vehicles

Claims (1)

It is an automatic braking device that determines the possibility of collision with an obstacle and performs automatic braking.
An information acquisition means for acquiring the distance to the obstacle, the relative speed between the own vehicle and the obstacle, and the own vehicle speed.
An oncoming vehicle determining means for determining whether or not the obstacle is an oncoming vehicle by comparing the calculated values based on the relative speed and the own vehicle speed with the determination threshold value.
A threshold setting means for setting the determination threshold according to the distance to the obstacle and the vehicle speed, and
Equipped with
The determination threshold value becomes a value that makes it difficult to determine that the vehicle is an oncoming vehicle as the distance to the obstacle increases, and a value that makes it difficult to determine that the vehicle is an oncoming vehicle as the own vehicle speed increases.
When the obstacle is determined to be an oncoming vehicle by the oncoming vehicle determining means, automatic braking is regulated.
An automatic braking device characterized by that.

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