JP6156048B2 - Vehicle system - Google Patents

Description

  The present invention relates to a vehicle system.

  As a conventional vehicle system, for example, in Patent Document 1, the presence or absence of a blind spot area caused by an oncoming vehicle is detected by photographing with an outside camera, the blind spot area exists, and the driver continues the right turn operation. In such a case, a driving support device is disclosed that warns the driver that there is a collision risk and prompts the driver to drive slowly.

JP 2006-227811 A

  By the way, the driving assistance apparatus described in the above-mentioned Patent Document 1 may issue a warning regarding an object that cannot be visually recognized, for example, in a state where the driver of the host vehicle cannot directly visually recognize the object in the blind spot area. In such a case, there is a risk that the driving burden on the driver of the vehicle is increased.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a vehicle system that can suppress an increase in the driving load of the driver of the host vehicle.

  In order to achieve the above object, a vehicle system according to the present invention includes a detection device that detects an object around the host vehicle, and a blind spot area on the front side in the running direction of the host vehicle while the host vehicle is running. Control capable of executing own vehicle deceleration control for controlling the own vehicle and decelerating the own vehicle when the object detected by the detection device remains for a preset first predetermined time or longer. And a device.

  In the above vehicle system, the control device may be configured such that the object detected by the detection device is a moving body that approaches the host vehicle from a direction that intersects the traveling direction of the host vehicle. The host vehicle deceleration control can be executed.

  Further, in the above vehicle system, the control device is arranged on the front side in the traveling direction of the host vehicle based on the information on the object detected by the detection device and the information on the host vehicle set in advance. A target detection unit that detects the target object included in the blind spot region, and the target object detected by the target detection unit stays in the blind spot region on the front side in the traveling direction of the host vehicle for the first predetermined time or more. A stay determination unit that determines whether or not the vehicle is present, and the host vehicle deceleration control is executed based on a determination result by the stay determination unit.

  In the vehicle system, the control device changes the deceleration of the host vehicle by the host vehicle deceleration control based on the relative speed between the target object and the host vehicle detected by the detection device. Can be.

  Further, the vehicle system includes a support device capable of outputting alert information, and the control device starts the host vehicle deceleration control even after elapse of a preset second predetermined time or more. When the object detected by the detection device stays in the blind spot area on the front side in the traveling direction of the host vehicle, it is possible to execute the alert information output control for controlling the support device and outputting the alert information. It can be assumed that

  Further, in the vehicle system, the control device presets the object detected by the detection device in a blind spot area on the front side in the traveling direction of the host vehicle when the host vehicle starts. When the vehicle stays for the third predetermined time or longer, the vehicle can be controlled to control the vehicle and limit the acceleration of the vehicle can be executed.

  The vehicle system according to the present invention executes the own vehicle deceleration control when the object remains in the blind spot area on the front side in the traveling direction of the own vehicle, so that the object in the blind spot area is removed from the own vehicle. Since it can be relatively moved to the visually recognizable region, it is possible to prompt the driver to visually recognize the target object, and to increase the driving load on the driver of the host vehicle. .

FIG. 1 is a schematic configuration diagram illustrating an alerting system according to the first embodiment. FIG. 2 is a schematic diagram for explaining an example of the operation of the alerting system according to the embodiment. FIG. 3 is a schematic diagram illustrating an example of the operation of the alerting system according to the embodiment. FIG. 4 is a flowchart illustrating an example of a control flow in the alerting system according to the embodiment. FIG. 5 is a flowchart illustrating an example of a control flow in the alerting system according to the second embodiment. FIG. 6 is a schematic diagram illustrating an example of the operation of the alerting system according to the third embodiment. FIG. 7 is a schematic diagram illustrating an example of the operation of the alerting system according to the third embodiment. FIG. 8 is a diagram illustrating an example of a calculation accelerator opening map in the alerting system according to the third embodiment. FIG. 9 is a flowchart illustrating an example of a control flow in the alerting system according to the third embodiment.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

[Embodiment 1]
FIG. 1 is a schematic configuration diagram illustrating an alerting system according to the first embodiment.

  An alerting system 1 as a vehicle system according to the present embodiment shown in FIG. 1 is mounted on a host vehicle 2. The host vehicle 2 is typically a four-wheeled vehicle. This alerting system 1 typically has an object that exists in a blind spot by controlling the host vehicle 2 itself when there is an object that stays in a blind spot such as a pillar under certain conditions in the host vehicle 2. Is in the driver's field of view to promote the driver's awareness. Thereby, this alerting system 1 suppresses that the driving | running load by the driver | operator of the own vehicle 2 increases. The alerting system 1 of the present embodiment is realized by mounting the components shown in FIG.

  Specifically, as shown in FIG. 1, the alert system 1 according to the present embodiment includes an object detection sensor 3 as a detection device, a host vehicle state detection device 4, and an HMI (Human Machine Interface) as a support device. A device 5, a braking (braking) device 6, a driving device 7, and an ECU (Electronic Control Unit) 8 as a control device are provided.

  The object detection sensor 3 detects an object around the host vehicle 2. The object detected by the object detection sensor 3 is, for example, a moving body such as a pedestrian, a bicycle, another vehicle (two-wheeled vehicle, four-wheeled vehicle) existing within a predetermined range around the host vehicle 2. The object detection sensor 3 uses, for example, millimeter wave radar, radar using infrared rays, laser radar using laser light, short-range radar such as UWB (Ultra Wide Band) radar, audible sound waves or ultrasonic waves. You may use sonar. The object detection sensor 3 detects an object around the host vehicle 2 and detects a relative physical quantity indicating a relative relationship between the detected object and the host vehicle 2. The object detection sensor 3 can detect, for example, the relative position (coordinate system), the relative speed (m / s), the relative distance (m), etc., between the host vehicle 2 and the object as the relative physical quantity.

  In addition, although the detection apparatus of this embodiment demonstrated as what is the object detection sensor 3, for example, periphery monitoring CCD cameras (imaging apparatus), such as a front camera, a back camera, and a left and right side camera, etc. You may use the image recognition apparatus etc. which detect the surrounding object of the own vehicle 2 by analyzing the image data which imaged the circumference | surroundings. In addition, the detection apparatus according to the present embodiment includes, for example, a roadside device installed on a roadside such as an intersection using wireless communication or the like and an infrastructure such as a VICS (Vehicle Information and Communication System) center. Various infrastructure information may be acquired by cooperation, and the object around the own vehicle 2 may be detected based on the acquired infrastructure information.

  The own vehicle state detection device 4 detects the state of the own vehicle 2 on which the alert system 1 is mounted. The host vehicle state detection device 4 includes, for example, a vehicle speed sensor that detects the vehicle speed of the host vehicle 2, an accelerator sensor that detects an accelerator opening corresponding to an accelerator pedal operation amount (accelerator depression amount) by the driver, and a driver brake. A brake sensor for detecting the amount of pedal operation (the amount of brake depression) is included.

  The HMI device 5 can output driving support information (HMI information) for supporting driving of the driver in the host vehicle 2. The HMI device 5 is an in-vehicle device that provides driving assistance by providing driving assistance information to the driver. The driving support information includes, for example, warning information described later. The HMI device 5 includes, for example, a display, a speaker, and the like provided in the passenger compartment of the host vehicle 2. The display is a visual information display device that outputs visual information (graphic information, character information). The speaker is an auditory information (voice) output device that outputs auditory information (voice information, sound information). As the HMI device 5, an existing device in the passenger compartment of the host vehicle 2, for example, a display or a speaker of a navigation system may be used. The HMI device 5 may be configured to include, for example, a haptic information output device that outputs haptic information such as handle vibration, seat vibration, pedal reaction force, and the like in addition to the display and the speaker.

  The braking device 6 is mounted on the host vehicle 2 and can brake the host vehicle 2. The braking device 6 includes a brake pad, a disk rotor, and the like, and generates a braking force on each wheel of the host vehicle 2 by a frictional force generated by these. The drive device 7 is mounted on the host vehicle 2 and can drive the host vehicle 2. The drive device 7 includes a power source for traveling of the host vehicle 2 such as an internal combustion engine and an electric motor, a transmission, a power transmission device, and the like, and a driving force is applied to the drive wheels of the host vehicle 2 by the power generated by the power source. Is generated.

  The ECU 8 controls driving of each part of the host vehicle 2 and includes an electronic circuit mainly composed of a known microcomputer including a CPU, a ROM, a RAM, and an interface. For example, the ECU 8 is electrically connected to various sensors and detectors such as the object detection sensor 3 and the host vehicle state detection device 4 described above, and receives an electric signal corresponding to the detection result. Moreover, ECU8 is electrically connected to each part of the own vehicle 2, such as the HMI apparatus 5, the braking device 6, and the drive device 7, and outputs a drive signal to these. The ECU 8 outputs a drive signal to each part of the host vehicle 2 by executing a stored control program based on various input signals and various maps input from various sensors, detectors, etc. To control.

  The ECU 8 of the present embodiment controls the braking device 6 of the host vehicle 2 to decelerate the host vehicle 2 when there is an object that stays in a blind spot such as a pillar under certain conditions. Vehicle deceleration control can be executed, thereby suppressing an increase in driving load by the driver of the host vehicle 2.

  Specifically, the ECU 8 stays in the blind spot area on the front side in the traveling direction of the host vehicle 2 during the traveling of the host vehicle 2 for the first predetermined time or more set in advance. If it is, the host vehicle deceleration control is executed. Here, the first predetermined time is arbitrarily set in advance according to, for example, actual vehicle evaluation, and is a determination time set to determine whether or not the object is staying in the blind spot area. is there.

  The blind spot area of the host vehicle 2 is basically determined in advance according to, for example, the form and size of the host vehicle 2, the positional relationship between the driver's seat and the pillar, the driver's eyepoint assumed, and the like. . The ECU 8 of the present embodiment stores in advance, as the host vehicle parameters, the form and dimensions of the host vehicle 2, the positional relationship between the driver's seat and the pillar, the assumed driver's eyepoint, and the like. The blind spot area on the front side in the traveling direction of the host vehicle 2 is defined in accordance with various arrangement relationships. The ECU 8 may sense, for example, the position of the head of the driver sitting in the driver's seat of the host vehicle 2 and finely adjust (correct) the blind spot area accordingly.

  In the following description, a case where the host vehicle deceleration control is performed as part of driving support at an intersection will be described. That is, the ECU 8 according to the present embodiment, when the object detected by the object detection sensor 3 is a moving body that approaches the host vehicle 2 from a direction that intersects the traveling direction of the host vehicle 2, Execute deceleration control.

  Hereinafter, a specific example of the ECU 8 will be described with reference to FIG. As an example, the ECU 8 shown in FIG. 1 includes an HMI control unit 81, a braking (brake) control unit 82, a drive control unit 83, a blind spot determination unit 84, and the like in terms of functional concept. The HMI control unit 81 controls the HMI device 5. The braking control unit 82 controls the braking device 6. The drive control unit 83 controls the drive device 7.

  The blind spot determination unit 84 determines whether or not the target object remains in the blind spot area on the front side in the traveling direction of the host vehicle 2. Here, the blind spot determination unit 84 includes a target detection unit 84a and a stay determination unit 84b.

  The target detection unit 84a is included in the blind spot area on the front side in the traveling direction of the host vehicle 2 based on the information on the target detected by the target detection sensor 3 and the information on the host vehicle 2 set in advance. Detect objects. Here, the information of the target detected by the target detection sensor 3 is a relative physical quantity indicating the relative relationship between the target detected by the target detection sensor 3 and the host vehicle 2 as described above. In addition, as described above, the information on the host vehicle 2 set in advance includes the form and size of the host vehicle 2, the positional relationship between the driver's seat and the pillar, the assumed driver's eyepoint, and the like. This is a host vehicle parameter that defines a blind spot area on the front side in the traveling direction. Based on these pieces of information, the object detection unit 84a detects an object included in a blind spot area on the front side in the traveling direction in which the driver turns his / her line of sight while the vehicle 2 is traveling forward. Here, in more detail, the object detection unit 84a, from among the objects included in the blind spot area on the front side in the traveling direction of the own vehicle 2, from the direction intersecting with the traveling direction of the own vehicle 2. Detecting moving objects approaching Here, the moving body approaching the host vehicle 2 from the direction intersecting the traveling direction of the host vehicle 2 is, for example, a pedestrian or bicycle trying to cross the traveling path of the host vehicle 2, or the host vehicle 2. It is another vehicle or the like that travels toward an intersection where the host vehicle 2 is about to pass through an intersection traveling road that intersects the traveling road.

  The stay determination unit 84b determines whether or not the object detected by the object detection unit 84a remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a first predetermined time or more. Here, the stay determination unit 84b is a front object in the traveling direction of the host vehicle 2 as a moving object approaching the host vehicle 2 from a direction intersecting the traveling direction of the host vehicle 2 as an object detected by the target detection unit 84a. It is determined whether or not it remains in the blind spot area on the side for a first predetermined time or more.

  And the said brake control part 82 controls the braking device 6 of the own vehicle 2 based on the determination result by the stay determination part 84b, and performs the own vehicle deceleration control which decelerates the own vehicle 2. FIG. That is, the braking control unit 82 is a moving object that approaches the host vehicle 2 from a direction that intersects the traveling direction of the host vehicle 2, here the target detected by the target detection unit 84 a by the stay determination unit 84 b. When the vehicle 2 is determined to remain in the blind spot area on the front side in the traveling direction of the host vehicle 2 for the first predetermined time or longer, the host vehicle deceleration control for decelerating the host vehicle 2 is executed. At this time, the HMI control unit 81 may control the HMI device 5 so as to output a display, a sound, or the like indicating the detection state of the object or the own vehicle deceleration control.

  On the other hand, the braking controller 82 detects that the object detected by the object detector 84a (the moving body approaching the host vehicle 2 from the direction intersecting the traveling direction of the host vehicle 2) is detected by the stay determining unit 84b. If it is determined that the vehicle 2 does not exist in the blind spot area on the front side in the traveling direction, or if it exists, the existing time is determined to be less than the first predetermined time, the host vehicle deceleration control is not executed.

  As a result, the ECU 8 intersects the object detected by the object detection sensor 3, here the traveling direction of the host vehicle 2, in the blind spot area on the front side in the traveling direction of the host vehicle 2 while the host vehicle 2 is traveling. The host vehicle deceleration control can be executed when the moving body approaching the host vehicle 2 from the direction remains for the first predetermined time or longer. The host vehicle deceleration control executed by the ECU 8 configured as described above is a control for controlling the braking device 6 of the host vehicle 2 to decelerate the host vehicle 2 as described above. In addition, the host vehicle deceleration control is performed by positioning an object hidden in a blind spot area on the front side in the traveling direction of the host vehicle 2 in a directly visible region while the host vehicle 2 is traveling. This corresponds to the driving attention awakening control (running blind spot avoidance control during driving) that prompts the driver to visually recognize the object.

  2 and 3 are schematic diagrams illustrating an example of the operation of the alerting system according to the embodiment.

  For example, as illustrated in FIG. 2, the object A approaching the host vehicle 2 from the direction intersecting the traveling direction of the host vehicle 2 is forward of the host vehicle 2 in the traveling direction while the host vehicle 2 is traveling. In some cases, the relative positional relationship with the host vehicle 2 is in an equilibrium state in a state in which it is within the blind spot region T on the side. In such a case, the ECU 8 controls the braking device 6 of the host vehicle 2 to decelerate the host vehicle 2 when the time during which the object A stays in the blind spot region T is equal to or longer than the first predetermined time. Execute deceleration control. Thereby, the alerting system 1 can change the relative positional relationship between the blind spot area T on the front side in the traveling direction and the object A during deceleration of the host vehicle 2, as illustrated in FIG. The equilibrium state can be overcome. Thereby, the alerting system 1 can prevent the target object A from being located in the blind spot region T of the driver of the host vehicle 2 as much as possible.

  As a result, the alerting system 1 can directly recognize the object A in the blind spot area T from the own vehicle 2 by executing the host vehicle deceleration control when the object A remains in the blind spot area T. It can be moved relative to the area. Therefore, the alerting system 1 can prompt the driver to visually recognize the object A, and can alert the driver in a more natural manner. Compared to a case where a warning regarding an object is immediately issued, an increase in the driving load on the driver of the host vehicle 2 can be suppressed.

  Note that the braking control unit 82 of the ECU 8 may control the deceleration of the host vehicle 2 to a fixed size that is set in advance when the host vehicle deceleration control is executed, or variable control depending on the situation. May be. For example, the braking control unit 82 may change the deceleration of the host vehicle 2 by the host vehicle deceleration control based on the relative speed between the target object detected by the target detection sensor 3 and the host vehicle 2. In this case, for example, the braking control unit 82 relatively increases the deceleration as the relative speed between the object and the host vehicle 2 is relatively lower, and the relative speed between the object and the host vehicle 2 is relatively higher. The higher the value, the smaller the deceleration. Thereby, this alerting system 1 can decelerate the own vehicle 2 with an appropriate deceleration according to the moving speed of the object, the vehicle speed of the own vehicle 2, etc. in the own vehicle deceleration control. The target object can be moved relative to a region that is directly visible from the host vehicle 2 more quickly. In this case, the braking control unit 82 sets the upper limit value of the deceleration of the host vehicle 2 by the host vehicle deceleration control according to the inter-vehicle distance between the succeeding vehicle and the host vehicle 2 detected by the target detection sensor 3. It may be. In this case, the braking control unit 82 relatively increases the upper limit value of the deceleration as the inter-vehicle distance between the succeeding vehicle and the host vehicle 2 is relatively longer, and the inter-vehicle distance between the succeeding vehicle and the host vehicle 2 is relatively higher. The shorter the value is, the lower the upper limit value of the deceleration is relatively lowered. As a result, the alert system 1 ensures that the distance between the host vehicle 2 and the following vehicle is sufficiently secured and sufficient safety is secured, and the object in the blind spot area is more quickly moved from the host vehicle 2. Relative movement to a directly visible region can be performed.

  FIG. 4 is a flowchart illustrating an example of a control flow in the alerting system according to the embodiment. An example of the control flow in the alerting system 1 will be described with reference to the flowchart of FIG. Note that these control routines are repeatedly executed at a control cycle of several ms to several tens of ms.

  First, the target detection unit 84a of the ECU 8 detects a target based on the detection result of the target detection sensor 3 (step ST1). Here, the object detection unit 84a approaches the host vehicle 2 from a direction intersecting with the traveling direction of the host vehicle 2 among the objects included in the blind spot area on the front side in the traveling direction of the host vehicle 2. Detect moving objects.

  Next, the stay determination unit 84b of the ECU 8 retains the target object (moving body) detected by the target detection unit 84a in step ST1 in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a first predetermined time or more. It is determined whether or not (step ST2).

  The ECU 8 detects that the object detection unit 84a does not detect the object (moving body) by the stay determination unit 84b, or the object detected by the object detection unit 84a is a blind spot area on the front side in the traveling direction of the host vehicle 2. When it is determined that the user has not stayed for the first predetermined time or more (step ST2: No), the process returns to step ST1 and the subsequent processing is repeated.

  In the brake control unit 82 of the ECU 8, the object (moving body) detected by the object detection unit 84a is staying in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a first predetermined time or more by the stay determination unit 84b. Is determined (step ST2: Yes), the host vehicle 2 is controlled to execute host vehicle deceleration control. That is, the braking control unit 82 controls the braking device 6 to start decelerating the host vehicle 2 at a specified deceleration (step ST3).

  Next, the stay determination unit 84b determines whether or not the object detected by the target detection unit 84a in step ST1 is out of the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST4).

  When it is determined by the stay determination unit 84b that the object detected by the target detection unit 84a remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST4: No), the ECU 8 proceeds to step ST3. Return and repeat the following process.

  The braking control unit 82 determines that the object detected by the object detection unit 84a has deviated from the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST4: Yes). 6 is finished, the deceleration of the host vehicle 2 is terminated, the host vehicle deceleration control is terminated (step ST5), and this control flow is terminated.

  According to the alerting system 1 described above, the target detection sensor 3 and the ECU 8 are provided. The object detection sensor 3 detects an object around the host vehicle 2. When the target object detected by the target detection sensor 3 remains in the blind spot area on the front side in the travel direction of the host vehicle 2 during the travel of the host vehicle 2 for a first predetermined time or longer, It is possible to execute host vehicle deceleration control that controls the host vehicle 2 to decelerate the host vehicle 2. Therefore, the alert system 1 executes the own vehicle deceleration control when the object remains in the blind spot area on the front side in the traveling direction of the own vehicle 2, so that the object in the blind spot area is removed from the own vehicle 2. Since it can be relatively moved to a visually recognizable region, the driver can be prompted to visually recognize the object, and an increase in the driving load on the driver of the host vehicle 2 can be suppressed.

[Embodiment 2]
FIG. 5 is a flowchart illustrating an example of a control flow in the alerting system according to the second embodiment. The vehicle system according to the second embodiment is different from the first embodiment in that alert information is output under a predetermined condition. In addition, about the structure, operation | movement, and effect which are common in embodiment mentioned above, the overlapping description is abbreviate | omitted as much as possible. Moreover, about each structure of the system for vehicles, FIG. 1 etc. are referred suitably (this is the same also in embodiment described below).

  The alert system 201 (see FIG. 1) as the vehicle system according to the present embodiment includes the above-described HMI device 5 (see FIG. 1) as a support device that can output alert information.

  Then, the ECU 8 of this embodiment starts the own vehicle deceleration control, and the object detected by the object detection sensor 3 is forward in the traveling direction of the own vehicle 2 even if a preset second predetermined time or more has elapsed. The alert information output control for controlling the HMI device 5 and outputting the alert information can be executed when it remains in the blind spot area. That is, the ECU 8 has started the own vehicle deceleration control in order to move the target object that has remained in the blind spot area ahead of the traveling direction in the host vehicle 2 for the first predetermined time or longer to the outside of the blind spot area. , The alert information output control is executed when it remains in the blind spot area for a certain time (second predetermined time) or longer. In this case, for example, the ECU 8 controls the HMI device 5 and outputs, as alerting information, a display or sound indicating that the object (moving body) is present in the blind spot area on the front side in the traveling direction. Here, the second predetermined time is arbitrarily set in advance according to, for example, actual vehicle evaluation and the like, and a determination time set to determine whether or not the object is staying in the blind spot area. It is.

  More specifically, the stay determination unit 84b of the ECU 8 of the present embodiment is configured such that the target detected by the target detection unit 84a is the traveling direction in the host vehicle 2 after the host vehicle deceleration control is started by the braking control unit 82. It is determined whether or not the vehicle stays in the blind spot area on the front side for a second predetermined time or longer. And the HMI control part 81 controls the HMI apparatus 5 of the own vehicle 2 based on the determination result by the stay determination part 84b, and performs alerting information output control.

  In other words, the HMI control unit 81 indicates that the object has remained in the blind spot area on the front side in the traveling direction of the host vehicle 2 for the second predetermined time or longer after the host vehicle deceleration control is started by the stay determination unit 84b. When it is determined, the alert information output control is executed. On the other hand, the HMI control unit 81 determines that the object has moved out of the blind area on the front side in the traveling direction of the host vehicle 2 before the second predetermined time has elapsed since the host vehicle deceleration control was started by the stay determination unit 84b. If determined, the alert information output control is not executed.

  As a result, the alerting system 201 outputs alerting information for the first time when the target object remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 even when the host vehicle deceleration control is executed. Information output control can be executed to alert the driver that an object is present in the blind spot area.

  The ECU 8 may use the host vehicle deceleration control and the alert information output control in combination, but it is preferable not to perform the host vehicle deceleration control when the alert information output control is performed. As a result, the alert system 201 can avoid the automatic deceleration of the host vehicle 2 and the output of alert information at the same time, so that the driving load on the driver of the host vehicle 2 can be increased in this respect as well. Can be suppressed.

  Next, an example of the control flow in the alerting system 201 will be described with reference to the flowchart of FIG. Again, descriptions overlapping with those in FIG. 4 are omitted as much as possible.

  When the stay determination unit 84b of the ECU 8 determines that the target detected by the target detection unit 84a in step ST4 remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST4: No), After starting the vehicle deceleration control, it is determined whether or not a second predetermined time has elapsed (step ST206). The ECU 8 returns to step ST3 and repeats the subsequent processes when the stay determination unit 84b determines that the second predetermined time or more has not elapsed after the host vehicle deceleration control is started (step ST206: No). .

  The HMI control unit 81 of the ECU 8 switches to display and sound alert when the stay determination unit 84b determines that the second predetermined time or more has elapsed after the host vehicle deceleration control is started (step ST206: Yes). (Step ST207), and this control flow ends. That is, after starting the own vehicle deceleration control, the HMI control unit 81 remains in the blind spot area on the front side in the traveling direction of the own vehicle 2 even if the second predetermined time or more has elapsed. If it is determined that the alert information is output, the HMI device 5 is controlled to start alert information output control for outputting alert information. At this time, the braking control unit 82 ends the host vehicle deceleration control.

  The alerting system 201 described above executes the subject vehicle deceleration control when the subject remains in the blind spot region on the front side in the traveling direction of the subject vehicle 2, so that the subject within the blind spot region is 2 can be relatively moved to a visually recognizable region, so that the driver can be urged to visually recognize the object, and an increase in the driving load on the driver of the host vehicle 2 can be suppressed.

  Furthermore, the alerting system 201 described above includes the HMI device 5 that can output alerting information. Then, after the host vehicle deceleration control is started, the ECU 8 causes the object detected by the object detection sensor 3 to enter the blind spot area on the front side in the traveling direction of the host vehicle 2 even if a predetermined second predetermined time or more elapses. When it stays, the alert information output control for controlling the HMI device 5 and outputting the alert information can be executed.

  Therefore, the alerting system 201 can perform alerting with increasing or decreasing strength in stages by executing the own vehicle deceleration control and the alerting information output control in stages. That is, the alerting system 201 executes alerting information output control when the object continues to stay in the blind spot area after prompting the object to be visually recognized by the own vehicle deceleration control, and It is possible to alert the presence of an object in the blind spot area. As a result, the alerting system 201 can more appropriately suppress an increase in the driving load on the driver of the host vehicle 2.

  Note that the alerting system 201 may further control the braking device 6 to change the braking pattern so that the driver is alerted. In this case, for example, when switching from the own vehicle deceleration control to the alert information output control, the alert system 201 urges the driver to alert the driver by making the braking pattern different from that during the own vehicle deceleration control. After that, the alert information output control may be started. Thereby, the alerting system 201 can suppress the increase in the driving load of the driver of the own vehicle 2 more appropriately.

[Embodiment 3]
6 and 7 are schematic diagrams for explaining an example of the operation of the alerting system according to the third embodiment. FIG. 8 is a diagram illustrating an example of a calculation accelerator opening map in the alerting system according to the third embodiment. FIG. 9 is a flowchart illustrating an example of a control flow in the alerting system according to the third embodiment. The vehicle system according to the third embodiment is different from the first and second embodiments in that the host vehicle acceleration restriction control is executed under a predetermined condition.

  In the alert system 301 (see FIG. 1) as the vehicle system according to the present embodiment, the ECU 8 can execute the host vehicle acceleration restriction control. When the host vehicle 2 starts, the ECU 8 detects that the target detected by the target detection sensor 3 remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a preset third predetermined time or longer. The host vehicle acceleration limiting control for controlling the host vehicle 2 and limiting the acceleration of the host vehicle 2 can be executed. Here, the third predetermined time is arbitrarily set in advance according to, for example, actual vehicle evaluation, and is a determination time that is set to determine whether or not the object remains in the blind spot area. is there.

  More specifically, the stay determination unit 84b of the ECU 8 of the present embodiment causes the object detected by the target detection unit 84a when the host vehicle 2 starts to move to the blind spot area on the front side in the traveling direction of the host vehicle 2. It is determined whether or not the vehicle remains for a third predetermined time. Here, the stay determination unit 84b is not limited to a moving body that approaches the host vehicle 2 from a direction that intersects the traveling direction of the host vehicle 2, and includes a moving body that runs side by side with the host vehicle 2. It is determined whether or not the detected object remains in the blind spot area for a third predetermined time or more.

  And the said drive control part 83 controls the drive device 7 of the own vehicle 2 based on the determination result by the stay determination part 84b, and performs the own vehicle acceleration restriction | limiting control which restrict | limits the acceleration of the own vehicle 2. FIG. That is, when the host vehicle 2 starts, the drive control unit 83 causes the stay determination unit 84b to cause the target detected by the target detection unit 84a to remain in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a third predetermined time or more. If it is determined that the vehicle is in the vehicle, the host vehicle acceleration limiting control for limiting the acceleration of the host vehicle 2 is executed.

  On the other hand, the drive control unit 83 may detect that the object detected by the object detection unit 84a by the stay determination unit 84b does not exist or exists in the blind spot area on the front side in the traveling direction of the host vehicle 2. If it is determined that the existing time is less than the third predetermined time, the host vehicle acceleration restriction control is not executed.

  As a result, when the subject vehicle detected by the subject detection sensor 3 remains in the blind spot area on the front side in the traveling direction of the subject vehicle 2 when the subject vehicle 2 starts, The host vehicle acceleration restriction control can be executed. The host vehicle acceleration restriction control executed by the ECU 8 configured as described above is control for controlling the drive device 7 of the host vehicle 2 to limit the acceleration of the host vehicle 2 as described above. And further speaking, the host vehicle acceleration limiting control places the object hidden in the blind spot area on the front side in the traveling direction of the host vehicle 2 in the area where the host vehicle 2 starts, This corresponds to start warning alert control (start dead angle avoidance control) that prompts the driver of the host vehicle 2 to visually recognize the object.

  For example, as illustrated in FIG. 6, an object A such as another vehicle (a side-by-side vehicle) positioned in front of the host vehicle 2 when the host vehicle 2 starts up is a blind spot on the front side in the traveling direction of the host vehicle 2. In some cases, the relative positional relationship with the host vehicle 2 is in an equilibrium state in a state in the region T. In such a case, the ECU 8 controls the host vehicle 2 to limit the acceleration of the host vehicle 2 by controlling the host vehicle 2 when the time during which the object A stays in the blind spot region T is equal to or longer than the third predetermined time. Execute control. As a result, the alerting system 301 changes the relative positional relationship between the blind spot area T on the front side in the running direction and the object A during acceleration restriction when the host vehicle 2 starts, as illustrated in FIG. And the equilibrium state can be overcome. Accordingly, the alerting system 301 can prevent the object A from being positioned as much as possible in the blind spot region T of the driver of the host vehicle 2.

  As a result, the alerting system 301 executes the subject vehicle acceleration restriction control when the subject A remains in the blind spot region T when the subject vehicle 2 starts, so that the subject A in the blind spot region T is Relative movement to a region that is directly visible from the vehicle 2 can be performed. Therefore, the alerting system 301 can prompt the driver to visually recognize the object A when the host vehicle 2 starts, and can alert the driver in a more natural manner. Furthermore, an increase in the driving load on the driver of the host vehicle 2 can be suppressed.

  Here, for example, the drive control unit 83 limits the accelerator opening for calculation used to calculate the driving force, and controls the drive device 7 based on the limited accelerator opening for calculation, thereby controlling the vehicle 2. The host vehicle acceleration limit control for limiting the acceleration is executed. The calculation accelerator opening and the driving force generated by the driving device 7 have a relationship such that the driving force generated by the driving device 7 is relatively increased as the calculation accelerator opening is relatively increased. When executing the host vehicle acceleration limit control, the drive control unit 83 causes the drive device 7 to generate the limit by restricting the calculation accelerator opening as compared with the case where the host vehicle acceleration limit control is not performed. The driving force can be limited, and the acceleration of the host vehicle 2 can be limited.

  The drive control unit 83 calculates the calculation accelerator opening based on, for example, a calculation accelerator opening map (or a mathematical model corresponding thereto) illustrated in FIG. Here, in the calculation accelerator opening map illustrated in FIG. 8, the horizontal axis indicates the actual accelerator opening (corresponding to the actual accelerator depression amount), and the vertical axis indicates the calculation accelerator opening. The calculation accelerator opening map describes the relationship between the actual accelerator opening and the calculation accelerator opening. The calculation accelerator opening degree map is stored in the storage unit of the ECU 8 after the relationship between the actual accelerator opening and the calculation accelerator opening is set in advance based on actual vehicle evaluation and the like. In this calculation accelerator opening map, the calculation accelerator opening (solid line L2) applied when executing the own vehicle acceleration restriction control is applied when the own vehicle acceleration restriction control is not executed. It is a relatively small value with respect to (dotted line L1). Here, the accelerator opening for calculation (solid line L2) applied when the host vehicle acceleration restriction control is executed increases the actual accelerator opening so that the restriction is gradually released after a predetermined time has elapsed. It is set so that it gradually converges to the dotted line L1 as it goes on. Note that the accelerator opening for calculation applied when the host vehicle acceleration restriction control is executed is not limited to the characteristic shown by the solid line L2, but may be the characteristic shown by the solid line L3, for example. The drive control unit 83 calculates the accelerator opening for calculation from the actual accelerator opening detected by the host vehicle state detection device 4 based on the solid line L2 or the solid line L3 of the calculation accelerator opening map, and calculates the calculated accelerator opening. The host vehicle acceleration restriction control is executed by restricting the driving force generated by the driving device 7 based on the calculation accelerator opening.

  Next, an example of a control flow in the alerting system 301 will be described with reference to the flowchart of FIG.

  First, the ECU 8 determines whether or not the host vehicle 2 has shifted to a start based on the detection result of the host vehicle state detection device 4 (step ST301). When the ECU 8 determines that the host vehicle 2 has not started (step ST301: No), the control flow ends.

  The object detection unit 84a of the ECU 8 detects the object based on the detection result of the object detection sensor 3 (step ST302) when it is determined that the host vehicle 2 has shifted to start (step ST301: Yes).

  Next, the stay determination unit 84b of the ECU 8 determines whether or not the object detected by the target detection unit 84a in step ST302 stays in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a third predetermined time or more. Determination is made (step ST303).

  The ECU 8 causes the stay determination unit 84b to detect that the object detection unit 84a does not detect the object, or the object detected by the object detection unit 84a is a third predetermined area in the blind spot area on the front side in the traveling direction of the host vehicle 2. When it is determined that it has not stayed for more than the time (step ST303: No), the process returns to step ST302 and the subsequent processing is repeated.

  The drive control unit 83 of the ECU 8 is determined by the stay determination unit 84b that the object detected by the target detection unit 84a stays in the blind spot area on the front side in the traveling direction of the host vehicle 2 for a third predetermined time or more. In the case (step ST303: Yes), the host vehicle 2 is controlled to execute host vehicle acceleration restriction control. That is, the drive control unit 83 controls the drive device 7 to start limiting acceleration of the host vehicle 2 (step ST304).

  Next, the stay determination unit 84b determines whether or not the object detected by the target detection unit 84a in step ST302 is out of the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST305).

  When it is determined by the stay determination unit 84b that the object detected by the target detection unit 84a remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST305: No), the ECU 8 proceeds to step ST304. Return and repeat the following process.

  When it is determined by the stay determination unit 84b that the object detected by the target detection unit 84a has deviated from the blind spot area on the front side in the traveling direction of the host vehicle 2 (step ST305: Yes), the drive control unit 83 7, the acceleration limitation of the host vehicle 2 is terminated, the host vehicle acceleration limitation control is terminated (step ST306), and this control flow is terminated.

  In the above description, the ECU 8 controls the driving device 7 to limit the driving force generated by the driving device 7, thereby executing the own vehicle acceleration limiting control for limiting the acceleration of the own vehicle 2. However, the present invention is not limited to this. For example, the braking control unit 82 of the ECU 8 controls the braking device 6 and continues braking even when the brake pedal is released by the driver and the braking operation is released when the host vehicle 2 starts, so that the amount of creep torque can be increased. The host vehicle acceleration limiting control for limiting the acceleration of the host vehicle 2 and the acceleration of the host vehicle 2 may be executed. Even in this case, the alerting system 301 can obtain an operation equivalent to the above.

  The alerting system 301 described above executes the subject vehicle deceleration control when the subject remains in the blind spot region on the front side in the traveling direction of the subject vehicle 2, so that the subject within the blind spot region is 2 can be relatively moved to a visually recognizable region, so that the driver can be urged to visually recognize the object, and an increase in the driving load on the driver of the host vehicle 2 can be suppressed.

  Furthermore, in the alert system 301 described above, the object detected by the object detection sensor 3 is set in advance in the blind spot area on the front side in the traveling direction of the host vehicle 2 when the host vehicle 2 starts. 3. When the vehicle stays for a predetermined time or longer, it is possible to control the host vehicle 2 and execute host vehicle acceleration limit control for limiting the acceleration of the host vehicle 2.

  Therefore, the alert system 301 controls the host vehicle acceleration restriction when the target object remains in the blind spot area on the front side in the traveling direction of the host vehicle 2 when the host vehicle 2 shifts from the stopped state to the start. Since the object in the blind spot area can be relatively moved to the area that can be visually recognized from the own vehicle 2 by executing the above, it is possible to prompt the driver to visually recognize the object. The increase in the driving load of the second driver can be suppressed.

  In addition, the system for vehicles which concerns on embodiment of this invention mentioned above is not limited to embodiment mentioned above, A various change is possible in the range described in the claim. The vehicle system according to the present embodiment may be configured by appropriately combining the components of the embodiments described above.

  In the above description, the vehicle system has been described as performing vehicle deceleration control as part of driving support at an intersection, but the present invention is not limited thereto. That is, the ECU 8 according to the present embodiment can detect the subject vehicle even when the subject detected by the subject detection sensor 3 is not a moving body that approaches the subject vehicle 2 from the direction intersecting the traveling direction of the subject vehicle 2. You may make it perform deceleration control.

  The braking device 6 described above is not limited to the above-described one, and for example, the host vehicle 2 may be braked and decelerated by an engine brake or a regenerative brake in a hybrid vehicle.

1,201,301 Alert system (vehicle system)
2 Own vehicle 3 Target detection sensor (detection device)
4 Own vehicle state detection device 5 HMI device (support device)
6 Braking device 7 Drive device 8 ECU (control device)
A Object T Blind spot area

Claims (7)

A detection device for detecting objects around the host vehicle;
When the subject detected by the detection device remains in a blind spot area on the front side in the running direction of the subject vehicle during the running of the subject vehicle for a predetermined first predetermined time or longer, the subject vehicle is And a control device capable of executing a host vehicle deceleration control for controlling and decelerating the host vehicle,
Vehicle system. The control device executes the host vehicle deceleration control when the object detected by the detection device is a moving body approaching the host vehicle from a direction intersecting the traveling direction of the host vehicle. To
The vehicle system according to claim 1. The said control apparatus is contained in the blind spot area | region ahead of the running direction in the said own vehicle based on the information of the said object detected by the said detection apparatus, and the information of the said own vehicle set beforehand. A target detection unit that detects a target object, and a stay determination that determines whether or not the target object detected by the target detection unit remains in the blind spot area on the front side in the traveling direction of the host vehicle for the first predetermined time or more. And executing the host vehicle deceleration control based on a determination result by the stay determination unit,
The system for vehicles according to claim 1 or 2. The control device changes the deceleration of the host vehicle by the host vehicle deceleration control based on the relative speed between the target object and the host vehicle detected by the detection device.
The vehicle system according to any one of claims 1 to 3. Equipped with a support device that can output alert information,
The control device detects the object detected by the detection device even if a predetermined second predetermined time or more has elapsed after the start of the host vehicle deceleration control. If it stays in, it is possible to execute the alert information output control for controlling the support device and outputting the alert information,
The system for vehicles according to any one of claims 1 to 4. The control device is configured such that, after the host vehicle has shifted from a stopped state to a start, the object detected by the detection device is preset in a blind spot area on the front side in the traveling direction of the host vehicle. 3 When the vehicle stays for a predetermined time or longer, the vehicle can be controlled, and the vehicle acceleration limit control for limiting the acceleration of the vehicle can be executed.
The vehicle system according to any one of claims 1 to 5. When the control device shifts to a start from a state where the host vehicle is stopped, the object detected by the detection device remains in a blind spot area on the front side in the traveling direction of the host vehicle. Even if the brake operation is released, the braking device is controlled to continue the braking, and the own vehicle acceleration limiting control for limiting the acceleration of the own vehicle can be executed.
The vehicle system according to any one of claims 1 to 5.

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