JP6443099B2 - Driving support device and driving support program - Google Patents

Description

  The present invention relates to a driving support device and a driving support program that support driving.

  2. Description of the Related Art Conventionally, a head-up display technique is known in which an image is projected onto a part of a windshield (windshield glass) of a vehicle, and the image is superimposed and displayed on a scene that a driver can see. For example, Patent Document 1 discloses a configuration in which a virtual leading vehicle image indicating a virtual leading vehicle that does not actually exist is superimposed and displayed to assist driving. In addition, a technique for controlling the inter-vehicle distance that is also employed in Auto Cruise Control (ACC) is also widely known. For example, in Patent Document 2, an appropriate inter-vehicle distance from a preceding vehicle is calculated based on the speed of the host vehicle, attention information is notified so as to maintain the calculated appropriate inter-vehicle distance, and driving is supported. A configuration is disclosed.

JP 2002-144913 A JP 2009-2111265 A

  By notifying the attention information disclosed in Patent Document 2 using the technology of the head-up display disclosed in Patent Document 1, the movement of the line of sight from the front of the driver (the traveling direction of the host vehicle) is suppressed. Attention information can be notified as an image. For example, by calculating an appropriate speed (recommended driving speed) and displaying an image that prompts an acceleration / deceleration operation up to the calculated speed, an acceleration / deceleration operation up to that speed can be prompted. However, in a configuration in which such an image is notified by a message (character string) display, a fine display, or the like, the content of the notification cannot be grasped unless the driver grasps the image with a central visual field. Therefore, the driver is forced to pay a certain amount of attention, and there is room for improvement in terms of providing the driver with information that supports driving. In the technique for controlling the inter-vehicle distance disclosed in Patent Document 2, acceleration / deceleration of the host vehicle is automatically controlled depending on, for example, whether or not a preceding vehicle exists. Therefore, if the driver's attention to the preceding vehicle is distracting, the vehicle will accelerate or decelerate in a situation where the driver is not aware that the vehicle will accelerate or decelerate from now on (while the driver is unconscious). The driver may be confused or feel anxious.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to appropriately provide the driver with information prompting the operation and information indicating the advance notice of the vehicle control, and appropriately supporting driving. It is in providing the driving assistance device and driving assistance program which can do.

According to the first aspect of the present invention, the validity determining means determines whether or not the notification for prompting the acceleration / deceleration operation is valid under the situation where the host vehicle is accelerating / decelerating by the operation of the driver. . When the effectiveness determining means determines that the notification is in a valid situation, the notification control means projects an image that prompts the acceleration / deceleration operation in a graphical manner on a part of the windshield of the host vehicle, and drives the image. Overlaid on the scenery that the person can see. The notification control means uses an animation image as an image and takes a single flow from the upper center side to the lower left and right end sides in the display area of the entire image until it moves, or the figure is the entire image. In the display area, the flow from the center to the left and right ends is a single flow. In an animation image that prompts a deceleration operation, the graphic moves at a relatively high speed, and in an animation image that prompts an acceleration operation, the graphic moves. The animation image is superimposed and displayed so as to move at a relatively slow speed.

  In other words, when the notification prompting the acceleration / deceleration operation becomes valid under the situation where the host vehicle is accelerating / decelerating due to the driver's operation, the image prompting the acceleration / deceleration operation is displayed not by a message display or a fine display but by a figure display. I did it. By displaying an image that prompts an acceleration / deceleration operation by displaying a diagram, the driver can grasp the content of the notification if the driver does not capture the image with the central visual field but the peripheral visual field. Thereby, while suppressing the movement of the line of sight from the front of the driver as much as possible, it is possible to cause the driver to quickly grasp the contents of the operation without forcing attention to the image, and driving can be supported appropriately.

According to the invention described in claim 2, whether or not the validity determination means is in a situation in which notification for notifying acceleration / deceleration control is effective under the situation where the host vehicle accelerates / decelerates under the control of the inter-vehicle distance control device. Determine. When the validity determination unit determines that the notification is in a valid state, the notification control unit displays information indicating the acceleration / deceleration control notification by displaying an image indicating the acceleration / deceleration control notification. . The notification control means uses an animation image as an image and takes a single flow from the upper center side to the lower left and right end sides in the display area of the entire image until it moves, or the figure is the entire image. In the display area, the flow from the center to the left and right ends is a single flow. In the animation image showing the deceleration control notice, the figure moves at a relatively high speed, and the animation shows the acceleration control notice. In the image, an animation image is superimposed and displayed so that the figure moves at a relatively slow speed.

  That is, when the notification for notifying the acceleration / deceleration control becomes effective under the situation where the host vehicle accelerates / decelerates under the control of the inter-vehicle distance control device, the information indicating the advance notice of the acceleration / deceleration control is notified. By notifying the information indicating the advance notice of acceleration / deceleration control, the driver can be made aware of preparations for acceleration / deceleration control. As a result, the driver can be aware that the vehicle will accelerate or decelerate from now on, so that the driver can be prevented from being confused or uneasy, and driving can be supported appropriately.

Functional block diagram showing an embodiment of the present invention The figure which shows the aspect in which the image is projected on a part of windshield Flow chart (Part 1) Flow chart (Part 2) Diagram showing the flow of animation images (Part 1) Diagram showing the flow of animation images (Part 2) Diagram showing the flow of an animation image (Part 3) Diagram showing the flow of animation images (Part 4) Diagram showing the flow of animation image (Part 5) Diagram showing the flow of animation image (Part 6)

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The driving support device 1 is mounted on a vehicle and includes a control unit 2 (corresponding to a control unit), a signal input unit 3, a storage unit 4, and an image projection unit 5. The driving support device 1 includes an object detection device 6, a navigation device 7, a traffic information acquisition device 8, a weather information acquisition device 9, a driver detection device 10, an inter-vehicle distance control device 11, an accelerator ECU (Electronic Control). Unit) 12 and the brake ECU 13 are connected to each other via a communication bus 14. The driving support device 1 shifts to an on state (starting state) by switching the accessory signal or the ignition signal from off to on, for example, and switches to an off state (stopped state) by switching the accessory signal or the ignition signal from on to off. Transition.

  The object detection device 6 is, for example, a laser range finder, a millimeter wave radar, a stereo camera, a compound eye camera, or the like, detects an object in front of the host vehicle using the front of the host vehicle as a detection area, and outputs an object detection signal including the detection result. The data is output to the driving support device 1 via the communication bus 14. When the object detection device 6 detects the presence of a preceding vehicle or a pedestrian as an object ahead of the host vehicle, the object detection device 6 outputs an object detection signal indicating that to the driving support device 1 via the communication bus 14. The navigation device 7 includes, as navigation-related information, the speed of the host vehicle (vehicle speed), the current position of the host vehicle, the destination set by the driver, the route from the current position to the destination, and the arrival predicted to arrive at the destination. A navigation signal including the predicted time is output to the driving support device 1 via the communication bus 14.

  The traffic information acquisition device 8 cooperates with the navigation device 7 to transmit a traffic information request signal including a road on which the vehicle is traveling and a route from the current position to the destination to the traffic information distribution server 15 via the communication network. To do. The traffic information distribution server 15 provides various traffic-related data (big data related to traffic) such as traffic jams, travel restrictions, accident-prone locations, road shapes (gradient, curve radius, etc.), road surface conditions (freezing, snow cover, etc.) Is stored and managed in association with a map. When the traffic information distribution server 15 receives the traffic information request signal from the traffic information acquisition device 8, the traffic information distribution server 15 extracts the traffic information around the road or route on which the host vehicle is included in the received traffic information request signal, A traffic information response signal including the extracted traffic information is transmitted to the traffic information acquisition device 8 via the communication network. When the traffic information acquisition device 8 receives the traffic information response signal from the traffic information distribution server 15, the traffic information acquisition device 8 extracts the traffic information included in the received traffic information response signal, and outputs the traffic information signal including the extracted traffic information. The data is output to the driving support device 1 via the communication bus 14.

  The weather information acquisition device 9 cooperates with the navigation device 7 to transmit a weather information request signal including a road on which the host vehicle is traveling and a route from the current position to the destination to the weather information distribution server 16 via the communication network. To do. The weather information distribution server 16 stores and manages various data relating to weather (big data relating to weather) such as snow, cloud movement, wind power, and wind direction in association with a map as weather information. When the weather information distribution server 16 receives the weather information request signal from the weather information acquisition device 9, the weather information distribution server 16 extracts the weather information around the road or route on which the host vehicle is running included in the received weather information request signal, A weather information response signal including the extracted weather information is transmitted to the weather information acquisition device 9 via the communication network. When the weather information acquisition device 9 receives the weather information response signal from the weather information distribution server 16, the weather information acquisition device 9 extracts the weather information included in the received weather information response signal, and outputs the weather information signal including the extracted weather information. The data is output to the driving support device 1 via the communication bus 14.

  The driver detection device 10 is a camera that captures the driver in the passenger compartment, a sensor that measures the driver's pulse, a sensor that measures the driver's heart rate, and the like, and detects the driver's state (physical condition). A state detection signal including the detection result is output to the driving support device 1 via the communication bus 14. The driver detection device 10 detects, for example, that the driver's line of sight movement is less than normal and the driver's attention is distracted, or the driver's pupil contracts more than normal, causing the driver to feel sleepy. If it is detected that the vehicle is driving, a state detection signal indicating that is output to the driving support device 1 via the communication bus 14.

  The inter-vehicle distance control device 11 cooperates with the object detection device 6 to calculate the speed at which the inter-vehicle distance between the host vehicle and the preceding vehicle can be maintained at an appropriate distance, and controls the accelerator ECU 12 and the brake ECU 13. The speed of the host vehicle is automatically adjusted based on the calculated speed. The inter-vehicle distance control device 11 can be switched between on and off states by a driver's operation. For example, when the driver turns on a switch disposed on the steering wheel, the vehicle shifts to an on state (starting state). When the is turned off, it shifts to an off state (stop state). The inter-vehicle distance control device 11 outputs an on / off state signal indicating an on / off state to the driving support device 1 via the communication bus 14. When the inter-vehicle distance control device 11 is in the off state, the host vehicle accelerates or decelerates due to the driver's accelerator operation and brake operation. On the other hand, when the inter-vehicle distance control device 11 is in the on state, the own vehicle is accelerated / decelerated by the control of the inter-vehicle distance control device 11, and if there is a preceding vehicle, the own vehicle is accelerated / decelerated following the behavior of the preceding vehicle. If there is no preceding vehicle, the host vehicle accelerates or decelerates so as to maintain the set speed set in advance by the driver.

  The control unit 2 includes a microcomputer having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and an I / O (Input / Output). The control unit 2 controls the overall operation of the driving support apparatus 1 by executing a stored computer program (including a driving support program). The signal input unit 3 controls the input of various signals from the various devices 6 to 11 via the communication bus 14. The storage unit 4 has a storage area for storing animation data of an animation image, which will be described in detail later, and a storage area for storing operation specifying data, which will be described later in detail.

  When the display command is input from the control unit 2, the image projecting unit 5 projects the image M onto a part of the windshield (windshield glass) G of the host vehicle as shown in FIG. Overlays the visible scene. In this case, the image projection unit 5 projects the image M onto the lower right corner of the windshield G when viewed from the driver, and projects the image M onto the portion where the movement of the line of sight from the front of the driver (the traveling direction of the host vehicle) is minimized. To do.

  The control unit 2 includes an effectiveness determination unit 2a (corresponding to the validity determination unit), an object presence determination unit 2b (corresponding to the object presence determination unit), a traffic information determination unit 2c (corresponding to the traffic information determination unit), Weather information determination unit 2d (corresponding to weather information determination unit), driver state determination unit 2e (corresponding to driver state determination unit), driving characteristic determination unit 2f (corresponding to driving characteristic determination unit), display control unit 2g (corresponding to notification control means). The control unit 2 executes the effectiveness determination unit 2a, the object presence determination unit 2b, the traffic information determination unit 2c, the weather information determination unit 2d, the driver state determination unit 2e, the driving characteristic determination unit 2f, and the display control unit 2g. It is configured by a computer program and realized by software.

  The validity determination unit 2a determines whether the notification (display of the image described above) is in a valid situation. The object presence determination unit 2b analyzes the object detection signal input from the object detection device 6 to the signal input unit 3, and determines whether there is a preceding vehicle or a pedestrian in front of the vehicle. The traffic information determination unit 2c analyzes a traffic information signal input from the traffic information acquisition device 8 to the signal input unit 3, and determines a traffic state around the road or route on which the host vehicle is traveling. The weather information determination unit 2d analyzes the weather information signal input to the signal input unit 3 from the weather information acquisition device 9, and determines the weather information around the road or route on which the host vehicle is traveling.

  The driver state determination unit 2e analyzes the state detection signal input from the driver detection device 10 to the signal input unit 3, and determines the state of the driver. The driving characteristic determination unit 2e is configured to detect sensor values of various sensors such as an acceleration sensor and a gyro sensor mounted on the vehicle, an accelerator operation (the amount of depression of the accelerator pedal and the number of depressions), and a brake operation (the amount of depression of the brake pedal and the number of depressions). ) And the like, and the driving characteristic data indicating the driving characteristic (trend) of the driver is stored in the storage unit 4 one by one and updated. And the driving characteristic determination part 2e reads the newest driving characteristic data memorize | stored in the memory | storage part 4, and determines a driving characteristic based on the read driving characteristic data. The driving characteristic data of the driver is data indicating, for example, the frequency of sudden acceleration, the frequency of sudden braking, the tendency to prefer high speed running, the tendency to prefer low speed running, and the like.

  The display control unit 2g reads the animation data stored in the storage unit 4 when the validity determination unit 2a determines that the notification is valid. Then, the display control unit 2g outputs a display command to the image projection unit 5, projects an animation image corresponding to the read animation data from the image projection unit 5 onto a part of the windshield G of the host vehicle, and displays the animation image. Is superimposed on the scenery that the driver can see.

  Next, the operation of the above configuration will be described with reference to FIGS. Here, a case where the inter-vehicle distance control device 11 is in an off state and a case where it is in an on state will be described. That is, a case where the own vehicle is accelerated / decelerated by the driver's accelerator operation and brake operation and a case where the own vehicle is accelerated / decelerated by the control of the inter-vehicle distance control device 11 will be described.

(1) When the inter-vehicle distance control device 11 is in an off state When the driving support device 1 is in an on state, the control unit 2 periodically generates a notification monitoring event at a predetermined cycle (for example, a cycle of several hundred milliseconds). When a notification monitoring event is generated, the notification monitoring process shown in FIG. 3 is started. When the notification monitoring process is started, the control unit 2 comprehensively analyzes various signals input from the object detection device 6, the navigation device 7, the traffic information acquisition device 8, the weather information acquisition device 9, and the driver detection device 10 ( S1), it is determined whether or not the notification is in a valid situation (S2, first procedure).

  More specifically, for example, when the control unit 2 determines that the course of the host vehicle is an accident-prone point, freezing, or the like, or when the weather is determined to be heavy rain or strong wind, the driver is sleepy. If it is determined that the route of the host vehicle is a road (back alley, steep slope, etc.) that the driver is not good at, the notification is determined to be valid. For example, when the control unit 2 determines that there is no preceding vehicle or a pedestrian, for example, the control unit 2 determines that the course of the host vehicle is a wide straight line, the path of the host vehicle is a road that does not make the driver weak. If it is determined that the notification is valid, the notification is determined to be valid. In this case, the control unit 2 may determine that the notification is valid if there is only one corresponding determination item. For example, each determination item may be weighted and set with a score. Alternatively, the score of the corresponding determination item may be added, and if the total score exceeds a preset reference point, it may be determined that the notification is in a valid situation. That is, the control unit 2 may combine the determination items in any way. If the above case does not apply, the control unit 2 determines that the notification is not in a valid state (no need to notify) (S2: NO), ends the notification monitoring process, returns, and monitors the next notification. Wait for the event to occur.

  When the control unit 2 determines that the notification is in a valid situation (S2: YES), the control unit 2 determines a target appropriate vehicle speed range based on the cause for which the notification is determined to be in a valid situation (S3). That is, the control unit 2 determines a relatively slow vehicle speed range as an appropriate vehicle speed range, for example, when it is determined that the course of the host vehicle is an accident occurrence point or the like and low-speed traveling is preferable. On the other hand, for example, when the preceding vehicle is not present and the course of the host vehicle is a wide straight line and high speed travel is preferable (no problem even if the vehicle travels at high speed), the control unit 2 uses the road traffic law or the like. A relatively fast vehicle speed range is determined as an appropriate vehicle speed range within a range not exceeding a prescribed speed limit.

  Next, the control unit 2 identifies the current vehicle speed based on the navigation signal input from the navigation device 7 (S4), and compares the identified current vehicle speed with the appropriate vehicle speed range (S5, S6). If the control unit 2 determines that the current vehicle speed is within the appropriate vehicle speed range (S5: NO, S6: NO), an animation image prompting a deceleration operation (brake operation) or an acceleration operation (accelerator operation) at that time It is determined whether or not is superimposed and displayed (S7, S8). When determining that the animation image is not being superimposed and displayed at that time (S7: NO, S8: NO), the control unit 2 ends the notification monitoring process, returns, and waits for the next notification monitoring event to occur.

  On the other hand, if the control unit 2 determines that the current vehicle speed is equal to or higher than the appropriate vehicle speed range, that is, the current vehicle speed is faster than the appropriate vehicle speed range (S5: YES), the controller 2 prompts a deceleration operation at that time. It is determined whether or not the animation image is being superimposed and displayed (S9). If the control unit 2 determines that the animation image prompting the deceleration operation is not being superimposed and displayed at that time (S9: NO), the control unit 2 reads out the animation data urging the deceleration operation from the storage unit 4. Then, the control unit 2 projects an animation image corresponding to the read animation data from the image projection unit 5 onto a part of the windshield, and superimposes and displays the animation image for prompting the deceleration operation on the scenery that the driver can see. Then, the superimposed display of the animation image prompting the deceleration operation is started (S10, second procedure).

  On the other hand, if the control unit 2 determines that the current vehicle speed is less than the appropriate vehicle speed range, that is, the current vehicle speed is too slower than the appropriate vehicle speed range (S6: YES), an animation image that prompts an acceleration operation at that time Is determined to be superimposed (S11). If the control unit 2 determines that the animation image that prompts the acceleration operation is not being superimposed and displayed at that time (S11: NO), the control unit 2 reads out the animation data that prompts the acceleration operation from the storage unit 4. Then, the control unit 2 projects the animation image corresponding to the read animation data from the image projection unit 5 onto a part of the windshield, and displays the animation image for urging the acceleration on the scenery that the driver can see. Then, the superimposed display of the animation image prompting the acceleration operation is started (S12, second procedure).

  When the control unit 2 starts the superimposed display of the animation image in this way, the control unit 2 returns to step S4. Thereafter, when the control unit 2 determines that the current vehicle speed is within the appropriate vehicle speed range from outside the appropriate vehicle speed range due to, for example, the driver performing a deceleration or acceleration operation (S5: NO, S6: NO), At that time, it is determined whether or not an animation image prompting a deceleration operation or an acceleration operation is being superimposed (S7, S8). If the control unit 2 determines that the animation image prompting the deceleration operation is being superimposed at that time (S7: YES), the control unit 2 ends the superimposed display of the animation image prompting the deceleration operation (S13), and the notification monitoring process To exit and wait for the next notification monitoring event to occur. If the control unit 2 determines that the animation image prompting the acceleration operation is being superimposed and displayed at that time (S8: YES), the control unit 2 ends the superimposed display of the animation image prompting the acceleration operation (S14) and notifies Ends the monitoring process and returns, and waits for the next notification monitoring event to occur. By ending the superimposed display of the animation image that prompts the deceleration operation and the acceleration operation in this way, the driver can grasp that the current vehicle speed is within the appropriate vehicle speed range from outside the appropriate vehicle speed range, It is possible to prompt the end of deceleration operation or acceleration operation.

  The control unit 2 performs superimposed display of animation images as shown in FIGS. That is, when the number of frames per unit time (for example, several milliseconds) is set to 8 frames, the control unit 2 displays a single flow (see FIG. 5) when displaying an animation image that prompts a deceleration operation. (Story) is performed in 4 frames (half of 8 frames), and on the other hand, when an animation image for prompting an acceleration operation is superimposed and displayed, one flow is performed in 8 frames as shown in FIG. In FIGS. 5 and 6, a single flow is performed until the circular figures (icons) A <b> 1 and A <b> 2 move from the center side toward the left and right end sides in the display area of the entire image. In the animation image that prompts the deceleration operation, the graphics A1 and A2 move at a relatively fast speed, while in the animation image that prompts the acceleration operation, the graphics A1 and A2 move at a relatively slow speed. That is, by superimposing and displaying animation images in which the figures A1 and A2 move relatively fast, it is possible to grasp that the speed of the host vehicle is too fast and prompt a deceleration operation. On the other hand, by displaying superimposed animation images in which the figures A1 and A2 move relatively slowly, it is possible to grasp that the speed of the host vehicle is too slow and prompt an acceleration operation. The driver's operation can be prompted by the difference in the moving speed of the figures A1 and A2. In addition, since the display is not based on message display or fine display, but on the display of the figure, the driver does not capture the animation image with the central visual field (the central part of the display area of the entire image). The content of the notification can be grasped by grasping at the end). Thereby, the line-of-sight movement from the front of the driver can be suppressed as much as possible, and safety during traveling can be ensured.

  7 and 8 may be used as another example of the animation image. In FIG. 7 and FIG. 8, a single flow is performed until the circular figures B1 to B3 move while enlarging from the upper center side toward the lower left and right end sides in the display area of the entire image. As shown in FIG. 7, in an animation image that prompts a deceleration operation, the figures B1 to B3 move at a relatively high speed. On the other hand, as shown in FIG. 8, in the animation image prompting the acceleration operation, the figures B1 to B3 move at a relatively slow speed. As still another example of the animation image, FIGS. 9 and 10 may be used. In FIG. 9 and FIG. 10, the linear (bar-shaped) figures C1 and C2 each move from the center side toward the left and right end sides in the entire image display area. As shown in FIG. 9, in the animation image prompting the deceleration operation, the figures C1 and C2 move at a relatively high speed. On the other hand, as shown in FIG. 10, in the animation image prompting the acceleration operation, the figures C1 and C2 move at a relatively slow speed.

  In the above description, the animation image is not superimposed when the current vehicle speed is within the appropriate vehicle speed range. However, an animation image indicating that the current vehicle speed is within the appropriate vehicle speed range may be superimposed and displayed. That is, an animation image that prompts an acceleration / deceleration operation that maintains the current vehicle speed may be superimposed and displayed. For example, if the flow of one animation image that prompts an acceleration operation is performed in 8 frames and the flow of an animation image that prompts a deceleration operation is performed in 4 frames, the current vehicle speed is within the appropriate vehicle speed range. It may be configured to perform one flow of an animation image indicating 6 in six frames.

(2) When the inter-vehicle distance control device 11 is in the on state The control unit 2 performs steps S1 to S4 described above. In this case, when the current vehicle speed is specified (S4), the control unit 2 acquires information on the preceding vehicle and the surrounding vehicles (S21), and the identification is performed in consideration of the acquired conditions of the preceding vehicle and the surrounding vehicles. The current vehicle speed and the appropriate vehicle speed range are compared (S5, S6). If the control unit 2 determines that the current vehicle speed is within the appropriate vehicle speed range (S5: NO, S6: NO), whether or not an animation image indicating the advance notice of deceleration or the advance notice of acceleration is being superimposed and displayed at that time. Is determined (S22, S23). When determining that the animation image is not being superimposed and displayed at that time (S22: NO, S23: NO), the control unit 2 ends the notification monitoring process, returns, and waits for the next notification monitoring event to occur.

  On the other hand, if the control unit 2 determines that the current vehicle speed is equal to or higher than the appropriate vehicle speed range, that is, the current vehicle speed is faster than the appropriate vehicle speed range (S5: YES), the controller 2 gives a notice of deceleration at that time. It is determined whether or not the animation image is being superimposed and displayed (S24). When determining that the animation image indicating the advance notice of deceleration is not being superimposed and displayed at that time (S24: NO), the control unit 2 reads out the animation data indicating the advance notice of deceleration from the storage unit 4. Then, the control unit 2 projects an animation image corresponding to the read animation data from the image projection unit 5 onto a part of the windshield, and superimposes and displays an animation image indicating the deceleration notice on the scenery that the driver can see. Then, the superimposed display of the animation image indicating the advance notice of deceleration is started (S25, second procedure).

  On the other hand, when the control unit 2 determines that the current vehicle speed is less than the appropriate vehicle speed range, that is, the current vehicle speed is too late than the appropriate vehicle speed range (S6: YES), an animation image indicating an advance notice of acceleration at that time point Is determined to be in a superimposed display (S26). When determining that the animation image indicating the advance notice of acceleration is not being superimposed and displayed at that time (S26: NO), the control unit 2 reads out the animation data indicating the advance notice of acceleration from the storage unit 4. Then, the control unit 2 projects an animation image corresponding to the read animation data from the image projection unit 5 onto a part of the windshield, and superimposes and displays an animation image indicating the acceleration notice on the scenery that the driver can see. Then, the superimposed display of the animation image indicating the advance notice of acceleration is started (S27, second procedure).

  When the control unit 2 starts the superimposed display of the animation image in this way, the control unit 2 returns to step S4. Thereafter, when the control unit 2 determines that the current vehicle speed is within the appropriate vehicle speed range from outside the appropriate vehicle speed range, for example, under the control of the inter-vehicle distance control device 11 (S5: NO, S6: NO), the deceleration is performed at that time. It is determined whether or not an animation image indicating the advance notice or the advance notice of acceleration is being superimposed (S22, S23). When determining that the animation image indicating the advance notice of deceleration is being superimposed and displayed at that time (S22: YES), the control unit 2 terminates the superimposed display of the animation image indicating the advance notice of deceleration (S28), and the notification monitoring process To exit and wait for the next notification monitoring event to occur. If the control unit 2 determines that the animation image indicating the advance notice of acceleration is being superimposed and displayed at that time (S23: YES), the control unit 2 ends the display of the animation image indicating the advance notice of acceleration (S29) and notifies Ends the monitoring process and returns, and waits for the next notification monitoring event to occur. By ending the superimposed display of the animation image indicating the advance notice of deceleration or the advance notice of acceleration in this way, the current vehicle speed is changed from outside the appropriate vehicle speed range to within the appropriate vehicle speed range, and the control of the inter-vehicle distance control device 11 is ended. Can be recognized by the driver.

  Also in this case, the control unit 2 performs superimposed display of the animation image as shown in FIGS. The graphics A1 and A2 move at a relatively high speed in the animation image that notifies the deceleration control, while the graphics A1 and A2 move at a relatively low speed in the animation image that notifies the acceleration control. The acceleration / deceleration control can be notified in advance based on the difference in the moving speeds of the figures A1 and A2, and the driver can be made aware of the preparation for acceleration / deceleration control (to be accelerated / decelerated from now on). That is, it is possible to avoid a situation in which the host vehicle is accelerated or decelerated under a situation in which the driver is not conscious, and the driver can be prevented from being confused or feeling uneasy. In particular, acceleration control is performed when there is no preceding vehicle or pedestrian from the state in which the preceding vehicle or pedestrian exists while the host vehicle is traveling at a low speed, but according to the present embodiment, the acceleration control is notified in advance. Thus, the driver can be made aware of the preparation for the acceleration control.

  As described above, according to the present embodiment, the following operational effects can be obtained. In the driving support device 1, when the inter-vehicle distance control device 11 is in an off state and the notification for prompting the acceleration / deceleration operation is valid under the situation where the host vehicle accelerates / decelerates by the driver's operation, the acceleration / deceleration operation is performed. The urging image is displayed by displaying an animation image instead of a message or a fine display. By accelerating the acceleration / deceleration operation by displaying an animation image, the driver can grasp the contents of the notification if he / she does not capture the image with the central visual field. This makes it possible to cause the driver to quickly grasp the content of the notification without forcing attention to the image while suppressing the movement of the driver's line of sight from the front as much as possible, and can appropriately support driving.

  In addition, when the inter-vehicle distance control device 11 is in an ON state and the notification for notifying the acceleration / deceleration control becomes effective under the situation where the own vehicle accelerates / decelerates under the control of the inter-vehicle distance control device 11, the acceleration / deceleration control is performed. The image to be notified in advance is also displayed by displaying an animation image. By notifying the acceleration / deceleration control in advance, the driver can be made aware of the preparation for the acceleration / deceleration control. Accordingly, it is possible to avoid a possibility that the driver is confused or feel uneasy, and driving can be appropriately supported. Even in this case, by giving advance notice of acceleration / deceleration control by displaying an animation image, the driver can grasp the content of the notification if he / she does not capture the image with the central visual field, but the driving can be performed more appropriately. Can help.

  In addition, the presence of objects around the vehicle, traffic information, weather information, driver status, driver The operation characteristics were comprehensively analyzed and judged. Thereby, it can be determined multifaceted whether the notification is in a valid situation. Furthermore, when the superimposed display of the image prompting the acceleration / deceleration operation or the image for notifying the acceleration / deceleration control is started, the image continues to be superimposed until the vehicle speed of the host vehicle is within the appropriate vehicle speed range. Superimposed display of images prompting acceleration / deceleration operations and images for notifying acceleration / deceleration control is ended. Thereby, the driver can grasp the timing when the driver finishes the acceleration / deceleration operation and the timing when the acceleration / deceleration control by the inter-vehicle distance control device 11 ends.

The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
Although the configuration for displaying an animation image has been illustrated as an example of the drawing, it may be classified by color. For example, when the vehicle speed of the host vehicle is too high, the display area of the entire image is displayed in red to display an image for prompting a deceleration operation or an image for notifying the deceleration control, while when the vehicle speed of the host vehicle is too slow, The display area may be blue, and an image for prompting an acceleration operation or an image for notifying acceleration control may be displayed. If the image prompting the deceleration operation or the image for warning the deceleration control is displayed in red, and the image prompting the acceleration operation or the image for warning the acceleration control is displayed in blue, the current vehicle speed is appropriate. An image indicating that it is within the vehicle speed range may be displayed in white. Further, the animation image may be displayed by being classified by color. Furthermore, such visual notification and auditory notification that outputs voice guidance may be used in combination.

  The presence of objects around the vehicle, traffic information, weather information, driver status, and driving characteristics of the driver are determined as to whether or not notifications for accelerating / decelerating operations and notifications for notifying acceleration / deceleration control are valid. The determination may be made using at least one of them without using all of them.

  The display of the animation image may change in conjunction with approaching the appropriate vehicle speed range from outside the appropriate vehicle speed range. For example, in FIGS. 5 and 6, if the vehicle approaches the appropriate vehicle speed range from the appropriate vehicle speed range or more, the circular figures A1 and A2 respectively move from the center side toward the left and right end sides in the entire image display area. On the other hand, if the moving speed changes gradually and approaches the appropriate vehicle speed range from less than the appropriate vehicle speed range, the round figures A1 and A2 are respectively left and right edges from the center side in the display area of the entire image. You may change so that the moving speed which moves toward the side may become high gradually.

  Notifications for notifying acceleration / deceleration control are not limited to projecting an animation image onto a part of the windshield of the vehicle and superimposing it on the scenery that the driver can see. For example, another method may be used such as displaying on a part of the meter panel or outputting sound.

  In the drawings, 1 is a driving support device, 2 is a control unit (control unit), 2a is an effectiveness determination unit (effectiveness determination unit), 2b is an object presence determination unit (object presence determination unit), and 2c is a traffic information determination unit. (Traffic information determination means), 2d is a weather information determination section (weather information determination means), 2e is a driver state determination section (driver state determination means), 2f is a driving characteristic determination section (driving characteristic determination means), 2g is A display control unit (notification control unit) 11 is an inter-vehicle distance control device.

Claims (11)

An effectiveness determination means (2a) for determining whether or not a notification for prompting an acceleration / deceleration operation is effective under a situation where the host vehicle is accelerating / decelerating by an operation of the driver;
When the validity determination unit determines that the notification is in an effective situation, an image that prompts the acceleration / deceleration operation with a graphical representation is projected onto a part of the windshield of the host vehicle, and the image is displayed to the driver. by superposing displayed scenery is visible, provided with, a broadcast control means (2 g) for notifying the information prompting the operation of acceleration and deceleration,
The notification control means uses an animation image as the image, and the figure moves as it expands from the upper center side toward the lower left and right end sides in the display area of the entire image, or the figure is an image. In the entire display area, the flow from the center to the left and right ends is a single flow. In an animation image that prompts a deceleration operation, the figure moves at a relatively high speed. In an animation image that prompts an acceleration operation, A driving support apparatus , wherein an animation image is superimposed and displayed so that a figure moves at a relatively slow speed . An effectiveness determination means (2a) for determining whether or not a notification for notifying acceleration / deceleration control is effective under a situation in which the host vehicle accelerates or decelerates under the control of the inter-vehicle distance control device (11);
Notification control for notifying information indicating the advance notice of acceleration / deceleration control by displaying an image showing the advance notice of acceleration / deceleration control when the validity determination means determines that the notification is in an effective state. Means (2g) ,
The notification control means uses an animation image as the image, and the figure moves as it expands from the upper center side toward the lower left and right end sides in the display area of the entire image, or the figure is an image. In the entire display area, the flow from the center to the left and right ends is a single flow. In the animation image showing the deceleration control notice, the figure moves at a relatively high speed, and the acceleration control notice is displayed. A driving support apparatus , wherein an animation image is superimposed and displayed so that a figure moves at a relatively slow speed in the animation image shown . In the driving support device according to claim 2,
The notification control means projects an image indicating a notice of acceleration / deceleration control onto a part of the windshield of the host vehicle, and displays the image superimposed on a scene that the driver can see, thereby giving a notice of acceleration / deceleration control. A driving assistance apparatus characterized by notifying information to be displayed. In the driving assistance device according to any one of claims 1 to 3,
An object presence determining means (2b) for determining the presence of an object around the vehicle;
The driving support device, wherein the validity determination unit determines whether the notification is in a valid state based on a determination result by the object presence determination unit . In the driving assistance device according to any one of claims 1 to 3 ,
A traffic information judging means (2c) for judging traffic information relating to traffic ;
The effectiveness determination means determines whether or not the notification is in an effective state based on a determination result by the traffic information determination means . In the driving assistance device according to any one of claims 1 to 3 ,
Weather information determination means (2d) for determining weather information related to the weather is provided,
The effectiveness determination means determines whether or not the notification is in an effective state based on a determination result by the weather information determination means . In the driving assistance device according to any one of claims 1 to 3 ,
Driver state determination means (2e) for determining the state of the driver is provided,
The effectiveness determination means determines whether or not the notification is in an effective state based on a determination result by the driver state determination means . In the driving assistance device according to any one of claims 1 to 3 ,
Driving characteristic determination means (2f) for determining the driving characteristic of the driver is provided,
The effectiveness determination means determines whether or not the notification is in an effective state based on a determination result by the driving characteristic determination means . In the driving assistance device according to any one of claims 1 to 8 ,
When the information control unit starts to notify the information, the information control unit continues to notify the information until the speed of the host vehicle is within the appropriate vehicle speed range, and when the speed of the host vehicle is within the appropriate vehicle speed range, the notification of the information is terminated. A driving support device characterized by that. In the control means (2) of the driving support device (1),
A first procedure for determining whether or not a notification for prompting an acceleration / deceleration operation is valid under a situation where the host vehicle is accelerating / decelerating by an operation of the driver;
When it is determined by the first procedure that the notification is in an effective state, an image prompting acceleration / deceleration operations in a graphical manner is projected onto a part of the windshield of the host vehicle, and the driver A second procedure for informing information prompting an acceleration / deceleration operation by superimposing and displaying on a viewable scene,
In the second procedure, an animation image is used as the image, and the figure moves as it expands from the upper center side toward the lower left and right end sides in the display area of the entire image, or the figure is an image. In the entire display area, the flow from the center to the left and right ends is a single flow. In an animation image that prompts a deceleration operation, the figure moves at a relatively high speed. In an animation image that prompts an acceleration operation, A driving support program , wherein an animation image is superimposed and displayed so that a figure moves at a relatively slow speed . In the control means (2) of the driving support device (1),
A first procedure for determining whether or not a notice for notifying acceleration / deceleration control is effective under a situation in which the host vehicle accelerates or decelerates under the control of the inter-vehicle distance control device (11);
When it is determined by the first procedure that the notification is in a valid state, an image indicating the advance notice of acceleration / deceleration is displayed to display information indicating the advance notice of acceleration / deceleration control. And execute the procedure of
In the second procedure, an animation image is used as the image, and the graphic is moved from the upper center side toward the lower left and right end sides in the display area of the entire image as one flow. In the display area of the entire image, the flow from the center to the left and right ends is a single flow. In the animation image indicating the deceleration control notice, the figure moves at a relatively high speed, and the acceleration control notice is displayed. A driving support program , wherein an animation image is superimposed and displayed so that a figure moves at a relatively slow speed in the animation image indicating

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