JP4606638B2 - Vehicle trajectory estimation device and vehicle travel safety device using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle trajectory estimation device that estimates a vehicle trajectory based on a yaw rate and a vehicle speed, and a vehicle travel safety device using the same.
[0002]
[Prior art]
An example of a vehicle trajectory estimation device that calculates a corner R based on a yaw rate and a vehicle speed and estimates the corner R as a trajectory of the host vehicle is disclosed in, for example, Japanese Patent Laid-Open No. 10-2954. Further, as disclosed in Japanese Patent Application Laid-Open No. 11-48826, for example, a technique for recognizing a preceding vehicle with respect to the own vehicle and automatically tracking the preceding vehicle by using such a vehicle trajectory estimation device. There is. Furthermore, as an image tracking device for recognizing a preceding vehicle with an image when automatically tracking the preceding vehicle in this way, for example, there is one disclosed in Japanese Patent Laid-Open No. 6-96397.
[0003]
By the way, in the vehicle trajectory estimation device that calculates the corner R based on the yaw rate and the vehicle speed and estimates this as the trajectory of the own vehicle, the corner R, that is, the trajectory of the own vehicle is calculated by the following equation.
r = v / y
r: Corner R [m]
v: Speed [m / s]
y: Yaw rate [rad / s]
As is apparent from this equation, when trying to estimate the trajectory to the vehicle speed range that is substantially determined to be in the stopped state, the sensing values of the vehicle speed and yaw rate are too small, and the calculated corner R, that is, the estimated vehicle trajectory is accurate. Instead, there were problems such as variations. For this reason, in the vehicle speed range that is substantially determined to be the stopped state, the trajectory of the own vehicle based on the above equation is not performed, and the own vehicle trajectory is inevitably estimated as a straight line.
[0004]
[Problems to be solved by the invention]
However, as shown in FIG. 5, when the trajectory X of the own vehicle 1 is estimated as a straight line, when the vehicle 1 is stopped in the middle of the corner, the oncoming vehicle 2 that is not the preceding vehicle in the straight direction of the own vehicle 1 is advanced. There was a possibility of causing a so-called false lock that is recognized as a car.
[0005]
Accordingly, an object of the present invention is to provide a vehicle trajectory estimation device capable of obtaining an estimated trajectory of a vehicle that is close to the actual vehicle even when the vehicle is stopped in the middle of a corner, and a vehicle travel safety device using the same. .
[0006]
[Means for Solving the Problems]
  In order to achieve the above object, a vehicle trajectory estimation apparatus according to claim 1 of the present invention includes a yaw rate detection means (for example, a yaw rate sensor 11 in the embodiment) for detecting the yaw rate of the vehicle, and a vehicle speed for detecting the vehicle speed of the vehicle. Detection means (for example, vehicle speed / wheel speed sensor 12 in the embodiment), and trajectory estimation means for estimating the vehicle trajectory based on detection results of the yaw rate detection means and the vehicle speed detection means (for example, trajectory estimation means 14 in the embodiment). And the vehicle has shifted from a running state to a substantially stopped state.The vehicle speed detected by the vehicle speed detecting means is lower than the first predetermined value indicating the high speed lower limit value.When the stop state determination means (for example, the stop state determination means 27 in the embodiment) and the stop state determination means determine that the vehicle has shifted to the stop state, the estimated trajectory before the stop state is determined. A stop trajectory estimation means (for example, a stop trajectory estimation means 28 in the embodiment) that is held as an estimated trajectory;Vehicle movement determination means for determining that the vehicle has moved a predetermined distance or more in a state where the vehicle speed detected by the vehicle speed detection means is equal to or higher than a second predetermined value indicating a low speed lower limit value smaller than the first predetermined value (for example, Vehicle movement determination means 30) in the embodiment, and when the vehicle movement determination means determines that the vehicle has moved more than the predetermined distance, holding of the estimated trajectory by the stop-time trajectory estimation means is stopped.It is characterized by that.
[0007]
  Thus, when the stop state determination means determines that the vehicle has substantially shifted to the stop state, the stop-time trajectory estimation means uses the estimated trajectory before the vehicle is substantially stopped as described above as the estimated trajectory of the vehicle. Hold. Therefore, even when the vehicle is stopped in the middle of a corner, it is possible to obtain an estimated trajectory of the vehicle that is close to the actual vehicle.
  The stop state determination means determines that the vehicle speed detected by the vehicle speed detection means is lower than the first predetermined value indicating the high speed lower limit value. It is possible to accurately and easily determine that the state has been changed.
  When the vehicle movement determining means determines that the vehicle has moved more than a predetermined distance in a state where the vehicle speed is equal to or higher than a second predetermined value indicating a lower speed lower limit value smaller than the first predetermined value, the estimation by the stop trajectory estimating means is performed. The holding of the trajectory will be stopped.
[0008]
  According to a second aspect of the present invention, there is provided a vehicle trajectory estimation device.Yaw rate detection means for detecting the yaw rate of the vehicle (for example, the yaw rate sensor 11 in the embodiment), vehicle speed detection means for detecting the vehicle speed of the vehicle (for example, the vehicle speed / wheel speed sensor 12 in the embodiment), the yaw rate detection means, and the vehicle speed Trajectory estimation means for estimating the trajectory of the vehicle based on the detection result of the detection means (for example, the trajectory estimation means 14 in the embodiment), and the vehicle has shifted from the running state to the substantially stopped state A stop state determination unit (for example, a stop state determination unit 27 in the embodiment) that determines that the vehicle speed detected by the vehicle speed detection unit is lower than a first predetermined value indicating a high speed lower limit value, and the stop state determination unit When it is determined that the vehicle has shifted to the stop state, the estimated trajectory before the stop state is maintained as the estimated trajectory of the vehicle. And a vehicle speed detected by the vehicle speed detecting means is equal to or higher than a second predetermined value indicating a low speed lower limit value smaller than the first predetermined value. Vehicle movement determination means (for example, vehicle movement determination means 30 in the embodiment) for determining that a predetermined time or more has passed in a certain state, and when the vehicle movement determination means determines that the predetermined time has elapsed , Stop holding the estimated trajectory by the stop trajectory estimating meansIt is characterized by that.
[0009]
  Thus, when the stop state determination means determines that the vehicle has substantially shifted to the stop state, the stop-time trajectory estimation means uses the estimated trajectory before the vehicle is substantially stopped as described above as the estimated trajectory of the vehicle. Hold. Therefore, even when the vehicle is stopped in the middle of a corner, it is possible to obtain an estimated trajectory of the vehicle that is close to the actual vehicle.
  stopThe stop state determination means determines that the vehicle speed detected by the vehicle speed detection means has shifted to a substantial stop state when the vehicle speed is lower than a first predetermined value indicating the high speed lower limit value. It can be accurately and easily determined that the state has been changed.
  The vehicle movement determination means is in a state in which it can be estimated that the vehicle has moved a predetermined distance or more after a predetermined time has elapsed in a state where the vehicle speed is equal to or higher than a second predetermined value indicating a low speed lower limit lower than the first predetermined value. When the determination is made, holding of the estimated trajectory by the stop trajectory estimating means is stopped.
[0016]
  Claims of the invention3The traveling safety device for a vehicle according to claim 1 is provided.Or 2While using the vehicle trajectory estimation device described above, the vehicle detection means (for example, the millimeter wave radar 19 and the stereo camera 20 in the embodiment) for detecting a vehicle in a predetermined region ahead of the vehicle traveling direction, and the vehicle detection means detect A preceding vehicle determination means (for example, a preceding vehicle determination ECU 24 in the embodiment) that determines a vehicle on the locus estimated by the locus estimation device among the vehicles as a preceding vehicle is provided. The preceding vehicle determined by the preceding vehicle determination means Acceleration / deceleration means (for example, brake hydraulic solenoid 17, throttle actuator 18, and acceleration / deceleration means 25 in the embodiment) for accelerating or decelerating the vehicle to follow the vehicle is provided.
[0017]
This allows the vehicle trajectory estimation device to obtain an estimated trajectory of the vehicle that is close to the actual vehicle even when the vehicle is stopped in the middle of a corner. The preceding vehicle determination means can accurately determine the vehicle on the travel locus estimated by the apparatus as the preceding vehicle, and the acceleration / deceleration means accelerates or decelerates the vehicle to follow the accurate preceding vehicle.
[0018]
  Claims of the invention4The traveling safety device for a vehicle according to claim 1 is provided.Or 2The vehicle trajectory estimation device described above, vehicle detection means for detecting a vehicle in a predetermined area ahead of the vehicle traveling direction, and of the vehicles detected by the vehicle detection means on the trajectory estimated by the trajectory estimation device A preceding vehicle determining means for determining the vehicle as a preceding vehicle, and a distance calculating means for calculating a distance to the detected vehicle based on the detection result of the vehicle detecting means (for example, the preceding vehicle determining ECU 24 and the stereo distance measuring ECU 23 in the embodiment) And a notification means (for example, the notification means 26 in the embodiment) for notifying when the distance to the preceding vehicle determined by the preceding vehicle determination means is equal to or less than a predetermined value. It is said.
[0019]
This allows the vehicle trajectory estimation device to obtain an estimated trajectory of the vehicle that is close to the actual vehicle even when the vehicle is stopped in the middle of a corner. The vehicle on the trajectory estimated by the apparatus can be accurately determined by the preceding vehicle determining means as the preceding vehicle, and the distance calculating means can calculate the distance with respect to the accurate vehicle.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS.
FIG. 1 shows a vehicle to which the present embodiment is applied. A yaw rate sensor (yaw rate detecting means) 11 for detecting the yaw rate of the vehicle is provided at the rear of the vehicle, and corresponds to a wheel. A vehicle speed / wheel speed sensor (vehicle speed detection means) 12 for detecting the vehicle speed and the wheel speed of the vehicle from the rotation pulse of the wheel is provided at the position.
[0021]
At the rear of the vehicle, there is provided a control ECU 15 including a trajectory estimating means 14 shown in FIG. 2 for estimating the trajectory of the own vehicle (vehicle) based on the detection results of the yaw rate sensor 11 and the vehicle speed / wheel speed sensor 12. .
[0022]
A brake hydraulic solenoid (acceleration / deceleration means) 17 for controlling the braking force of the vehicle and a throttle actuator (acceleration / deceleration means) 18 for controlling acceleration or deceleration of the vehicle are provided at the front of the vehicle. Yes. In addition, the front end of the vehicle receives a reflected wave from a millimeter-wave object transmitted forward, thereby detecting an object including a vehicle in a predetermined radar detection area at a relatively long distance forward in the vehicle traveling direction. A millimeter wave radar (vehicle detection means) 19 is provided.
[0023]
Furthermore, a stereo camera (vehicle detection means) 20 that detects an object including a vehicle in a predetermined camera detection area at a relatively far distance ahead of the vehicle traveling direction is provided in the vehicle at the position of the room mirror. An indicator 21 for displaying a warning or the like to the driver on the instrument panel, switches 22 shown in FIG. 2 in which operation input is performed by the driver in the vicinity of the indicator 21, a buzzer, a warning lamp, or the like The notification means 26 shown in FIG. 2 is provided.
[0024]
In addition, a stereo ranging ECU (distance calculation) that calculates the distance between the vehicle and the object in the camera detection area (that is, the distance from the vehicle to the detected vehicle) from the image received by the stereo camera 20 at the rear of the vehicle. Means) and the distance between the vehicle and the object in the radar detection area (that is, the distance from the vehicle to the detected vehicle) from the millimeter wave radar 19 transmission / reception time. Of the vehicle detected by the stereo camera 20 or the millimeter wave radar 19 from the distance between the object and the object in the camera detection area calculated by the stereo ranging ECU 23 and the locus estimated by the locus estimating device 14. It has a preceding vehicle determination ECU (preceding vehicle determination means, distance calculation means) 24 for determining a vehicle on the estimated locus as a preceding vehicle.
[0025]
As shown in FIG. 2, the control ECU 15 includes acceleration / deceleration means 25 for controlling the brake hydraulic solenoid 17 or the throttle actuator 18 to accelerate or decelerate the vehicle so as to follow the preceding vehicle determined by the preceding vehicle determination ECU 24. Is provided.
[0026]
The control ECU 15 is supplied with detection results from the yaw rate sensor 11 and the vehicle speed / wheel speed sensor 12, and further, operation results of the switches 22 in the yaw rate sensor 11. The trajectory estimation means 14 described above for estimating the trajectory of the vehicle based on the detection result of the vehicle speed / wheel speed sensor 12 and the operation result of the switches 22 is provided.
[0027]
In the present embodiment, the control ECU 15 further includes a stop state determination unit 27 that determines whether or not the vehicle has shifted from the traveling state to a substantially stopped state (hereinafter referred to as a substantially stopped state), and the stopped state. When the determination means 27 determines that the vehicle has shifted to a substantially stopped state, it includes a stop-time locus estimating means 28 that holds the estimated locus immediately before the vehicle is substantially stopped as the estimated locus of the vehicle. In the stop state determination means 27, the vehicle speed detected by the vehicle speed / wheel speed sensor 12 that the vehicle has shifted to the substantial stop state has decreased from a first predetermined value (specifically, 5 km / h) indicating the high speed lower limit value. It is determined by this.
[0028]
Further, in the present embodiment, the control ECU 15 has the second predetermined value (specifically, 0.4 km / h) indicating the low speed lower limit value in which the vehicle speed detected by the vehicle speed / wheel speed sensor 12 is smaller than the first predetermined value. ) In this state, the vehicle movement determination means 30 for determining that the vehicle has moved a predetermined distance (specifically, 20 m) or more, and the vehicle movement determination means 30 is in a state where the vehicle speed is equal to or higher than the second predetermined value. When it is determined that the vehicle has moved a predetermined distance or more, holding stop means 31 for stopping holding of the estimated trajectory by the stop trajectory estimating means 28 is provided. The holding stop means 31 regards the estimated trajectory of the vehicle as a straight line when the holding is stopped.
[0029]
The yaw rate sensor 11, the vehicle speed / wheel speed sensor 12, the trajectory estimation means 14, the stop state determination means 27, the stop-time trajectory estimation means 28, the vehicle movement determination means 30 and the holding stop means 31 of the control ECU 15 A trajectory estimation device 33 is configured.
[0030]
The trajectory estimation device 33, the millimeter wave radar 19, the stereo camera 20, the stereo ranging ECU 23, the preceding vehicle determination ECU 24, and the acceleration / deceleration means 25 of the control ECU 15 constitute a vehicle travel safety device 34. ing.
[0031]
Next, the process of selecting the vehicle trajectory (corner R) used by the trajectory estimation device 33 will be described with reference to the flowchart of FIG.
[0032]
First, the stop state determination means 27 determines whether or not the vehicle speed VSP of the host vehicle is equal to or higher than 5 km / h, which is a first predetermined value indicating the high speed lower limit value, from the detection result of the vehicle speed / wheel speed sensor 12. (Step S1). When VSP ≧ 5 km / h, that is, when the vehicle speed is high, a flag f_vycnrcal indicating that the vehicle speed is high is set (step S2). The first predetermined value of 5 km / h is the minimum vehicle speed at which an accurate sensing value can be obtained from the yaw rate sensor 11 and the vehicle speed / wheel speed sensor 12, in other words, the minimum vehicle speed at which it can be determined that the vehicle is in the running state ( In other words, when the vehicle speed falls below the first predetermined value, it can be determined that the vehicle is in a substantially stopped state), and the yaw rate sensor 11 and the accuracy of the vehicle speed / wheel speed sensor 12 are set.
[0033]
Then, DRUN indicating the travel distance of the vehicle used in step S13, which will be described later, is reset (step S3) and set to “not use the trajectory before stopping” (step S4).
[0034]
Next, it is determined whether or not the trajectory before the stop is used (step S5). In this case, since the “trajectory before the stop is not used” is set in step S4, the vehicle speed / wheel speed sensor 12 is set. Whether or not the vehicle speed VSP of the host vehicle is equal to or higher than 5 km / h, which is a first predetermined value indicating the high speed lower limit value, is determined (step S6). In this case, since VSP ≧ 5 km / h, based on the vehicle speed VSP of the vehicle based on the detection result of the vehicle speed / wheel speed sensor 12 and the detection result of the yaw rate sensor 11, the trajectory of the vehicle ( Corner R) is calculated (step S7).
r = v / y
r: Corner R [m]
v: Speed [m / s]
y: Yaw rate [rad / s]
[0035]
On the other hand, if VSP ≧ 5 km / h is not satisfied in step S1, that is, if the vehicle speed is low enough to be determined as a substantial stop state, it is determined whether or not the flag f_bycnrcal indicating that the vehicle speed is high is set (step S8). When f_bycnrcal is set, since the vehicle speed was high in the previous control cycle and switched to the low vehicle speed in the current control cycle, DRUN indicating the travel distance of the vehicle used in step S13 described later is reset (step S13). S9).
[0036]
Then, when the flag f_bycnrcal is not set in step S8 and after step S9, the flag f_bycnrcal is reset (step S10), and the vehicle speed VSP of the own vehicle is determined from the detection result of the vehicle speed / wheel speed sensor 12 by the low speed lower limit value. It is determined whether it is 0.4 km / h or more which is the second predetermined value shown (step S11). When VSP ≧ 0.4 km / h, that is, at a low vehicle speed of 5 km / h> VSP ≧ 0.4 km / h, control is performed to 3.6 with respect to DRUN indicating the travel distance of the vehicle in the previous control cycle. DRUN is rewritten to a value obtained by adding a value obtained by dividing the vehicle speed VSP by a value obtained by multiplying the time Ts corresponding to the processing period of the cycle (step S12). That is, the distance traveled at a low vehicle speed from the previous control cycle to the current control cycle is integrated.
[0037]
If VSP ≧ 0.4 km / h is not satisfied in step S11, that is, if the vehicle speed is extremely low and after step S12, whether the vehicle travel determination means 30 has accumulated distance DRUN traveled at a low vehicle speed of 20 m or more, which is a predetermined distance. It is determined whether or not (step S13). The predetermined distance of 20 m is set as an allowable travel distance in the setting of the estimated trajectory, and can of course be set to 10 m or 30 m. If DRUN ≧ 20 m, the travel distance is within an allowable range, so “use trajectory before stop” is set (step S14).
[0038]
Next, in step S5, it is determined whether or not the trajectory before the stop is used. In this case, since “use the trajectory before the stop” is set in step S14, the trajectory estimating unit 28 at the time of stop is determined. However, the vehicle trajectory (corner R) set in the previous control cycle is used (step S15). That is, the estimated trajectory before the actual stop state is maintained as the estimated trajectory of the own vehicle.
[0039]
On the other hand, if DRUN ≧ 20 m in step S13, it is determined that the travel distance at the low vehicle speed has become an unacceptable level, DRUN is set to 20 m (step S16), and the holding cancel unit 31 “ “Do not use a locus” is set (step S17).
[0040]
Next, in step S5, it is determined whether or not the trajectory before the stop is used. In this case, since “not use the trajectory before the stop” is set in step S17, in step S6, the vehicle speed / It is determined from the detection result of the wheel speed sensor 12 whether or not the vehicle speed VSP of the host vehicle is 5 km / h or more, which is a first predetermined value indicating a high speed lower limit value. In this case, since VSP ≧ 5 km / h, in other words, the vehicle speed VSP is lower than the first predetermined value, it is determined that the own vehicle locus (corner R) is a straight line (step S18).
[0041]
When the preceding vehicle determination ECU 24 determines that the vehicle on the estimated own vehicle locus is a preceding vehicle among the vehicles detected by the millimeter wave radar 19 and the stereo camera 20 based on the own vehicle locus estimated as described above. The ECU 15 accelerates or decelerates the vehicle so that the acceleration / deceleration means 25 follows the preceding vehicle determined by the preceding vehicle determination ECU 24.
[0042]
In the vehicle trajectory estimation device 33 according to the embodiment described above, when the stop state determination unit 27 determines that the vehicle has shifted to a substantial stop state, the stop-time trajectory estimation unit 28 substantially stops in this way. The estimated trajectory before becoming is held as the estimated trajectory of the vehicle. Therefore, as shown in FIG. 4, even when the vehicle is stopped in the middle of the corner, an estimated trajectory X of the own vehicle 1 that is close to the actual vehicle can be obtained, and the preceding vehicle is correctly determined without being erroneously locked to the oncoming vehicle 2. It will be possible. In addition, since it is not necessary to add a rudder angle sensor, an increase in cost can be minimized.
[0043]
Moreover, when the vehicle speed detected by the vehicle speed / wheel speed sensor 12 that the stop state determination means 27 has shifted to a substantial stop state has decreased from 5 km / h, which is the first predetermined value indicating the high speed lower limit value. Since it is determined, it can be accurately and easily determined that the vehicle has shifted to a substantial stop state.
[0044]
Further, when the vehicle movement determination means 30 is in a state where the vehicle speed is not less than 0.4 km / h which is a second predetermined value indicating a low speed lower limit value which is smaller than 5 km / h which is the first predetermined value, the vehicle has a predetermined distance. If it is determined that it has moved 20 m or more, the holding cancel unit 31 stops holding the estimated trajectory by the stop trajectory estimating unit 28. Therefore, this can be prevented when the vehicle moves at a low speed and it becomes inaccurate if the stored estimated trajectory is continuously used.
[0045]
Here, the vehicle movement determination means 30 has passed a predetermined time or more in a state where the vehicle speed detected by the vehicle speed / wheel speed sensor 12 is equal to or higher than a second predetermined value smaller than a first predetermined value indicating a low speed lower limit value. In addition, the holding stop means 31 stops holding the estimated trajectory by the stop trajectory estimating means 28 when the vehicle movement determining means 30 determines that the predetermined time has elapsed. It may be.
[0046]
Even with this configuration, the vehicle movement determination means 30 can estimate that the vehicle has moved a predetermined distance or more after a predetermined time has elapsed in a state where the vehicle speed is equal to or higher than the second predetermined value smaller than the first predetermined value. If it is determined that the vehicle has reached the state, the holding cancel unit 31 stops holding the estimated track by the stop-time track estimating unit 28, so that the vehicle moves at a low speed and continues to use the held estimated track. In this case, this can be prevented when it becomes inaccurate.
[0047]
Further, in the vehicle trajectory estimation device 33 according to the present embodiment, the holding stop means 31 regards the estimated trajectory of the vehicle as a straight line when the holding is stopped. If it becomes inaccurate if it continues to be used, this can be prevented and the estimated trajectory can be optimized at that time.
[0048]
Furthermore, in the vehicle travel safety device 34 of the present embodiment, the vehicle trajectory estimation device 33 can obtain an estimated trajectory of the vehicle that is close to the actual vehicle even when the vehicle trajectory is stopped in the middle of the corner. When the vehicle starts from a stopped state, the preceding vehicle determination ECU 24 can accurately determine the vehicle on the traveling locus estimated by the locus estimating device 33 as the preceding vehicle. The vehicle will be accelerated or decelerated to follow. Therefore, accurate follow-up traveling can be performed even when starting from a stopped state in the middle of a corner.
[0049]
The trajectory estimation device 33, the millimeter wave radar 19, the stereo camera 20, the stereo ranging ECU 23, and the preceding vehicle determination ECU 24 described above are used as the vehicle travel safety device 34, and are detected by the stereo ranging ECU 23 and the preceding vehicle determination ECU 24. When the distance between the preceding vehicle determined by the preceding vehicle determination ECU 24 and the own vehicle becomes equal to or less than a predetermined value, the control ECU 15 may notify the information by the notifying means 34 such as a buzzer or a warning lamp. .
[0050]
If comprised in this way, even if the locus | trajectory estimation apparatus 33 of a vehicle can obtain the estimated locus | trajectory of the own vehicle close | similar to the actual, even when it is in the stop state in the middle of a corner, At the time of departure, the preceding vehicle determination ECU 24 can accurately determine the vehicle on the locus estimated by the locus estimation device 33 as the preceding vehicle, and the stereo distance measurement ECU 23 and the preceding vehicle determination ECU 24 set the distance to the accurate vehicle. Since it can be calculated, even when starting from a stopped state in the middle of a corner, it is possible to accurately notify when the distance from the preceding vehicle is equal to or less than a predetermined value.
[0051]
【The invention's effect】
  As described above in detail, according to the vehicle trajectory estimation device according to claim 1 of the present invention, when the stop state determining means determines that the vehicle has substantially shifted to the stop state, the stop trajectory estimating means is Thus, the estimated trajectory before the vehicle is substantially stopped is held as the estimated trajectory of the vehicle. Therefore, even when the vehicle is stopped in the middle of the corner, an estimated trajectory of the vehicle that is close to the actual vehicle can be obtained, and the preceding vehicle can be determined correctly. In addition, since it is not necessary to add a rudder angle sensor, an increase in cost can be minimized.
  The stop state determining means determines that the vehicle speed detected by the vehicle speed detecting means is lower than 5 km / h, which is the first predetermined value indicating the high speed lower limit value, when the vehicle speed detecting means has shifted to a substantial stop state. Therefore, it is possible to accurately and easily determine that the vehicle has shifted to a substantially stopped state.
  When the vehicle movement determining means determines that the vehicle has moved more than a predetermined distance in a state where the vehicle speed is equal to or higher than a second predetermined value indicating a lower speed lower limit value smaller than the first predetermined value, the estimation by the stop trajectory estimating means is performed. The holding of the trajectory will be stopped. Therefore, this can be prevented when the vehicle moves at a low speed and it becomes inaccurate if the stored estimated trajectory is continuously used.
[0052]
  According to the vehicle trajectory estimation device of claim 2 of the present invention,When the stop state determination means determines that the vehicle has substantially shifted to the stop state, the stop-time trajectory estimation means retains the estimated trajectory before the vehicle is substantially stopped as described above as the estimated trajectory of the vehicle. Therefore, even when the vehicle is stopped in the middle of the corner, an estimated trajectory of the vehicle that is close to the actual vehicle can be obtained, and the preceding vehicle can be determined correctly. In addition, since it is not necessary to add a rudder angle sensor, an increase in cost can be minimized.
  The stop state determining means determines that the vehicle speed detected by the vehicle speed detecting means is lower than 5 km / h, which is the first predetermined value indicating the high speed lower limit value, when the vehicle speed detecting means has shifted to a substantial stop state. Therefore, it is possible to accurately and easily determine that the vehicle has shifted to a substantially stopped state.
  The vehicle movement determination means is in a state in which it can be estimated that the vehicle has moved a predetermined distance or more after a predetermined time has elapsed in a state where the vehicle speed is equal to or higher than a second predetermined value indicating a low speed lower limit lower than the first predetermined value. When the determination is made, holding of the estimated trajectory by the stop trajectory estimating means is stopped. Therefore, this can be prevented when the vehicle moves at a low speed and it becomes inaccurate if the stored estimated trajectory is continuously used.
[0056]
  Claims of the invention3According to the vehicle travel safety device described above, the vehicle trajectory estimation device can obtain an estimated trajectory of the vehicle that is close to the actual vehicle even when the vehicle is stopped in the middle of the corner. When the vehicle starts off, the vehicle on the traveling locus estimated by the locus estimation device can be accurately determined by the preceding vehicle determining means as the preceding vehicle, and the acceleration / deceleration means accelerates the vehicle so as to follow the accurate preceding vehicle. Or it will slow down. Therefore, accurate follow-up traveling can be performed even when starting from a stopped state in the middle of a corner.
[0057]
  Claims of the invention4According to the vehicle travel safety device described above, the vehicle trajectory estimation device can obtain an estimated trajectory of the vehicle close to the actual vehicle even when the vehicle is stopped in the middle of the corner. At the time of departure from the vehicle, the vehicle on the trajectory estimated by the trajectory estimation device can be accurately determined by the preceding vehicle determining means as the preceding vehicle, and the distance calculating means can calculate the distance to the accurate vehicle. . Therefore, even when starting from a stopped state in the middle of a corner, it is possible to accurately notify when the distance from the preceding vehicle becomes a predetermined value or less.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an embodiment of the present invention.
FIG. 2 is a block diagram showing an embodiment of the present invention.
FIG. 3 is a flowchart showing control contents of the trajectory estimation apparatus according to the embodiment of the present invention.
FIG. 4 is a plan view showing an estimated trajectory by the trajectory estimation apparatus according to the embodiment of the present invention.
FIG. 5 is a plan view showing an estimated trajectory by the trajectory estimation device.
[Explanation of symbols]
11 Yaw rate sensor (yaw rate detection means)
12 Vehicle speed / wheel speed sensor (vehicle speed detection means)
14 Trajectory estimation means
15 Control ECU (distance calculation means)
17 Brake hydraulic solenoid (acceleration / deceleration means)
18 Throttle actuator (acceleration / deceleration means)
19 Millimeter wave radar (vehicle detection means)
20 Stereo camera (vehicle detection means)
23 Stereo ranging ECU (distance calculation means)
24 preceding vehicle determination ECU (preceding vehicle determination means, distance calculation means)
25 Acceleration / deceleration means (acceleration / deceleration means)
26 Notification means
27 Stop state determination means
28 Stop time trajectory estimation means
30 Vehicle movement determination means
31 Holding stop means

Claims (4)

Yaw rate detection means for detecting the yaw rate of the vehicle;
Vehicle speed detecting means for detecting the vehicle speed of the vehicle;
A trajectory estimation device for a vehicle, comprising: a trajectory estimation unit that estimates a trajectory of the vehicle based on detection results of the yaw rate detection unit and the vehicle speed detection unit;
Stop state determination means for determining that the vehicle speed detected by the vehicle speed detection means is lower than a first predetermined value indicating a high speed lower limit value when the vehicle has shifted from a running state to a substantially stopped state;
When the stop state determination means determines that the vehicle has transitioned to the stop state, a stop-time trajectory estimation means that holds an estimated trajectory before the stop state as an estimated trajectory of the vehicle;
Vehicle movement determination means for determining that the vehicle has moved a predetermined distance or more in a state where the vehicle speed detected by the vehicle speed detection means is equal to or higher than a second predetermined value indicating a low speed lower limit lower than the first predetermined value; With
A vehicle trajectory estimation apparatus , wherein when the vehicle movement determination means determines that the vehicle has moved more than the predetermined distance, the stop trajectory estimation means stops holding the estimated trajectory . Yaw rate detection means for detecting the yaw rate of the vehicle;
Vehicle speed detecting means for detecting the vehicle speed of the vehicle;
A trajectory estimation device for a vehicle, comprising: a trajectory estimation unit that estimates a trajectory of the vehicle based on detection results of the yaw rate detection unit and the vehicle speed detection unit;
Stop state determination means for determining that the vehicle speed detected by the vehicle speed detection means is lower than a first predetermined value indicating a high speed lower limit value when the vehicle has shifted from a running state to a substantially stopped state;
When the stop state determination means determines that the vehicle has transitioned to the stop state, a stop-time trajectory estimation means that holds an estimated trajectory before the stop state as an estimated trajectory of the vehicle;
Vehicle movement determination means for determining that a predetermined time or more has elapsed in a state where the vehicle speed detected by the vehicle speed detection means is equal to or higher than a second predetermined value indicating a low speed lower limit value smaller than the first predetermined value. ,
A vehicle trajectory estimation apparatus that stops holding the estimated trajectory by the stop trajectory estimation means when the vehicle movement determination means determines that the predetermined time has elapsed . With use of the track estimating apparatus for a vehicle according to claim 1,
Vehicle detection means for detecting a vehicle in a predetermined area ahead of the vehicle traveling direction;
A preceding vehicle determination means for determining a vehicle on the trajectory estimated by the trajectory estimation device as a preceding vehicle among the vehicles detected by the vehicle detection means;
A vehicle travel safety device comprising acceleration / deceleration means for accelerating or decelerating the vehicle to follow the preceding vehicle determined by the preceding vehicle determining means. With use of the track estimating apparatus for a vehicle according to claim 1,
Vehicle detection means for detecting a vehicle in a predetermined area ahead of the vehicle traveling direction;
A preceding vehicle determination means for determining a vehicle on a locus estimated by the locus estimation device as a preceding vehicle among the vehicles detected by the vehicle detection means;
A distance calculation means for calculating a distance to the vehicle detected based on the detection result of the vehicle detection means,
A traveling safety device for a vehicle, comprising: a notifying unit that notifies when the distance to the preceding vehicle determined by the preceding vehicle determining unit is equal to or less than a predetermined value by the distance calculating unit.

Images