JPH08220225A - Inter-vehicle distance detecting device - Google Patents

Abstract

PURPOSE: To provide an inter-vehicle distance detecting device which can detect that one's own car enters a curve road from a straight line road. CONSTITUTION: In an inter-vehicle distance detecting device using a radio wave radar, a guide rail is detected (S101 and 102), or a clutter level detector judges (S104) that a curve road exists on condition that a detected signal level changes (S105 and 106) with the lapse of time, and the others are judged (S107) as a straight line road. Not only that one's own car travels on the curve road but also that it is going to enter the curve road from the straight line road can be detected by using a clutter level.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inter-vehicle distance detecting device which is mounted on an automobile and detects an inter-vehicle distance to a vehicle ahead.

[0002]

2. Description of the Related Art An inter-vehicle distance detecting device for an automobile is already on the market and used for preventing traffic accidents. FIG. 11 shows an example of the inter-vehicle distance detecting device. FIG.
Reference numeral 1 is an example of an FM-CW radar, and 1 is an inter-vehicle distance detecting device mounted on an automobile, which transmits an FM modulated signal output from a processor 2 forward from an antenna 3. The antenna 3 receives the radio wave reflected from the vehicle 4 or the like ahead, and the signal is processed by the processor 2 through the low-pass filter 5. The processor 2 calculates and displays the distance to the vehicle 4 ahead and the relative speed from the transmitted radio wave and the received radio wave. Also, when the distance to the vehicle ahead is in a dangerous distance range, an alarm is issued.

Such a conventional inter-vehicle distance detecting device sufficiently exhibits its function on a straight road. However, on a curved road, as shown in FIG. 12, when the vehicle is in a position E where a vehicle is about to enter a curved road from a straight road, or when the vehicle is in a position F while traveling on a curved road, a radio wave radar measurement is performed. The distance area G extends to the roadside and the outside thereof. Therefore, the guardrail outside the own lane,
It detects objects such as road signs and signs and measures the distance between them. Then, an alarm is issued according to the distance.

As described above, it is unnecessary to issue an alarm to an object outside the vehicle lane, which gives a driver discomfort. For this reason, even in the conventional art, when it is detected that a vehicle enters a curved road, the alarm is suppressed, or the detection distance is shortened to suppress the detection of an object on the road side.
As a method of detecting a curved road, a curved road is determined using a steering sensor or a yaw rate sensor, or a curved road is determined when a roadside guardrail is detected.

[0005]

However, in these conventional methods, the control is performed after the vehicle enters the curved road as shown in FIG. 12 (b), so that the vehicle at the position E in FIG. 12 (a) is controlled. It was not possible to judge the curved road before entering the curved road like. For this reason, when entering a curved road from a straight road, the target in front of the vehicle is lost, and various controls are performed on an object on the roadside that is not on the vehicle lane.

It is an object of the present invention to provide an inter-vehicle distance detecting device capable of detecting that a vehicle enters a curved road from a straight road. It is another object of the present invention to provide an inter-vehicle distance detection device that performs processing according to a curved road and can prevent a vehicle in front of the vehicle from being lost or an object on the road from being erroneously detected as a target on a vehicle lane. It is what

[0007]

In order to achieve the above object, the present invention provides a vehicle distance detecting apparatus using a radio wave radar, which comprises a guardrail detecting means, a clutter level detecting means, and the guardrail detecting means. Means is provided for determining that there is a curved road on the condition that the guardrail is detected or the signal level detected by the clutter level detection changes with time.

[0008]

The inter-vehicle distance detection device determines that there is a curved road by detecting the guardrail. When the guardrail is not on the roadside, it is determined that there is a curved road because the signal level of the detected clutter level changes with time. As a result, it is possible to detect whether the vehicle is traveling on a curved road or the vehicle is about to enter the curved road.

Further, the inter-vehicle distance detecting device suppresses an alarm when a curved road is judged, shortens the detection distance of the radio wave radar, changes the direction of the radio wave radar to the direction along the vehicle lane, etc. It is possible to add the means of.

[0010]

Embodiments of the present invention will be described below. Each of the following embodiments can be realized by an inter-vehicle distance detecting device using a radio wave radar as shown in FIG. (Embodiment 1) When a car enters a curved road from a straight road or when a car travels on a curved road, as shown in FIG. 12, the distance measurement area G of the radio wave radar is out of the vehicle lane and is on the roadside. Alternatively, the distance of an object located farther than that is measured.

In this case, when there is a guardrail on the roadside, the inter-vehicle distance detecting device measures the distance to the guardrail. At this time, the relationship between the distance between the guardrail and the host vehicle and the relative speed is such that the relative speed is close to the host vehicle speed, although the distance does not change much. This is because the guardrail is continuous and the vehicle travels along the guardrail, so there is little change in distance, and because the guardrail is a stationary target, the relative speed is close to the vehicle speed. Become.

In this embodiment, by utilizing this phenomenon, it is determined that there is a curved road when a signal characteristic of the guardrail is obtained. On the other hand, in the case of a curved road without a guardrail on the roadside, in the present embodiment, roadside clutter such as road signs, signs, trees, etc. on the roadside is detected, and the curved road is determined based on the change in the clutter level. While traveling on a straight road, the roadside clutter is not so much detected.
However, in the case of the situation shown in FIG. 12, the detection area of the inter-vehicle distance detection device extends to the roadside, so that the roadside clutter is picked up.

When entering a curved road from a straight road, a situation in which a target is detected on a straight road is changed to a situation in which roadside clutter is detected, so that the inter-vehicle distance detecting device suddenly picks up clutter. Further, the roadside clutter detected by the inter-vehicle distance detecting device continues to change while traveling on a curved road. In this embodiment, when a change in the clutter level is detected, it is determined that the vehicle is entering a straight road or a curved road or is traveling on a curved road.

A method of determining a curved road of the inter-vehicle distance detecting apparatus in this embodiment will be described with reference to the flowchart of FIG. The operation of FIG. 1 is performed at predetermined time intervals (for example, 40 ms). In step S101, the distance to the target and the relative speed are detected by a normal method.

In step S102, it is checked whether or not the change in distance to the target is substantially equal to the relative speed.
It is N when the target is a continuous object such as a guardrail, and Y when it is another object. In step S103, it is checked whether the change in distance is substantially equal to the vehicle speed. It is N when the target is a stationary object such as a guardrail, and Y when it is another object.

If both steps S102 and S103 are N, it is determined that the target is a guardrail and there is a curved road, and the process proceeds to step S104. Step S10
At 4, for example, a curve road determination flag is set. If Y in steps S102 and 103, the clutter level is detected by a normal method in step S105. An example of the clutter level detected here is shown in FIG.

In FIG. 2, the horizontal axis represents frequency f and the vertical axis represents level intensity. Further, (a) shows the clutter level detected in step S105 during the current processing operation, and (b) shows the clutter level detected during the previous processing operation. The frequencies indicated by are the frequencies selected in advance as the frequencies specific to the clutter.

In step S106, a change in clutter level is checked. Here, the change of the level of this time and the previous time is checked for each frequency. As a concrete method, the upper limit value and the lower limit value for level determination are obtained by multiplying the previous level by the coefficients α and β for each frequency. When the clutter level changes outside the upper and lower limits this time (Fig. 2,),
The vehicle is entering a curved road from a straight road and suddenly picks up clutter, or the vehicle is traveling on a curved road and the clutter on the roadside moves relatively as the vehicle travels. It is determined that the following is true, and the process proceeds to step S104.

On the other hand, if the current level is within the range between the upper limit value and the lower limit value, there is no change in the clutter level and it is determined that the target is not roadside clutter. That is, it is determined that the host vehicle is traveling on a straight road, and the process proceeds to step S107. In step S107, for example, a straight road determination flag is set. As described above, in the present embodiment, it is possible to determine the curved road while traveling on the curved road as in the conventional case, and the own vehicle, which was impossible in the past, enters the curved road from the straight road. It is possible to determine a curved road even at the time of performing.

By utilizing the above-described determination of the curved road and further providing appropriate means as described in the following embodiments, the target ahead of the curved road is lost when entering the curved road, or unnecessary reflection objects on the roadside are detected. On the other hand, it becomes possible to prevent unnecessary control. (Embodiment 2) In the first embodiment, the inter-vehicle distance detecting device detects a roadside guardrail, road sign, signboard, etc. as a stationary object even after it is determined to be a curved road. When such a stationary object is detected, it is necessary to suppress unnecessary alarms. An example in which the warning is suppressed when it is determined that the road is a curved road will be described below as a second embodiment of the present invention.

The time taken by the inter-vehicle distance detection device to detect the above-mentioned roadside stationary object is several seconds although it varies depending on the speed of the vehicle. Therefore, in the present embodiment, when a stationary object is detected for only a short time while entering a curved road or traveling on a curved road, it is determined that a stationary object on the roadside has been detected and an alarm is issued. To suppress unnecessary alarms.

However, if the alarm is not issued to all stationary objects, it is dangerous that the alarm is not issued even to a stopped vehicle on the lane of the vehicle. In this embodiment, in order to prevent such a danger, the alarm is suppressed for a fixed time or only for a short time according to the vehicle speed. Then, a normal alarm is issued to a stationary object that is detected after the prohibition time, to prevent danger.

A method of suppressing an alarm in the inter-vehicle distance detecting apparatus according to this embodiment will be described with reference to the flowchart of FIG. The operation of FIG. 3 is also performed at predetermined time intervals. In step S301, the distance to the target and the relative speed are detected by a normal method.

In step S302, the curve road determination process shown in FIG. 1 is performed, and the result is checked in step S303. As a result, if the straight road is determined, the process proceeds from step S303 to step S304,
Normal alarm processing is performed. If it is determined to be a curved road in step S303, it is checked in step S305 whether the target is a stationary object. As a concrete method for this, a means for judging from the relationship between the distance change and the vehicle speed, such as step S103 in FIG. 1 described above, is used.

When it is determined in step S305 that the target moves (N), the process proceeds to step S304,
Normal alarm processing is performed. If it is determined to be a stationary object (Y) in step S305, the alarm suppression time t is calculated in step S306. The alarm suppression time t is a constant value or a value according to the vehicle speed as shown in FIG. FIG.
Shows that the suppression time is shortened when the host vehicle speed is fast, and is lengthened when the host vehicle speed is slow.

In step S307, it is checked whether the time during which the target (stationary object) is detected (the time from the detection until the present) is shorter than the alarm suppression time t. Here, if the target detection time is shorter than the alarm suppression time t (Y), it is determined that the target is a roadside stationary object for the reason described above, and the alarm is suppressed in step S308. In step S307, if the alarm time is longer than the alarm suppression time (N), it is determined that the stationary object is not on the roadside but in the vehicle lane, and the process proceeds to step S304 to perform normal alarm processing.

(Embodiment 3) When it is determined that the road is a curved road,
In order to prevent the inter-vehicle distance detecting device from detecting an object on the road side, it is a simple and effective method to set the detection distance of the inter-vehicle distance detecting device short when it is determined to be a curved road. This example will be described as a third embodiment of the present invention with reference to the flowchart of FIG.

In step S501, the distance to the target and the relative speed are detected by the usual method. In step S502, the curve road determination process shown in FIG. 1 is performed, and the result is checked in step S503. As a result, if the determination (N) of the straight road is made, the result shown in FIG.
The operation of (3) is ended, and the processing proceeds to normal alarm processing and the like.

When it is determined that the road is a curved road in step S503 (Y), the process proceeds to step S504, and a distance X ₁ shorter than the normal detection distance of the inter-vehicle distance detecting device is set. This set distance X ₁ is set according to the own vehicle speed as shown in FIG. That is, when the vehicle speed is fast, the set distance X ₁ is set long, and when it is slow, it is set short. In step S505, the distance to the target captured by the inter-vehicle distance detection device is the distance X set in step S504.
_It is checked whether it is greater than ₁ . Here, if the target distance is larger than the distance X ₁ (Y), it is determined that the target is on the roadside and is a no target on the vehicle lane. Then, in step S507, for example, a no-target flag is set. If the target distance is smaller than the set distance X ₁ (N), it is determined that the target has been recognized in the vehicle lane, and step S
At 506, a flag for target recognition is set.

After that, the inter-vehicle distance detecting device uses the above flags to perform a normal alarm process and the like. (Fourth Embodiment) In the third embodiment, the set distance X ₁ is set based on the vehicle speed. However, when a stationary object such as a guardrail is detected after it is determined to be a curved road, the distance to the stationary object is set. If the set distance is X ₂ , more accurate processing becomes possible. This example will be described as Example 4 of the present invention with reference to the flowchart of FIG.

In step S701, the distance to the target and the relative speed are detected by the usual method. In step S702, the curved road determination process shown in FIG. 1 is performed, and the result is checked in step S703. As a result, if the straight road is determined (N), the result shown in FIG.
The operation of (3) is ended, and the processing proceeds to normal alarm processing and the like.

If it is determined that the road is a curved road in step S703 (Y), the flow advances to step S704 to check whether the target is a stationary object. If it is not a stationary object (N), the operation of FIG. 7 is terminated and the process proceeds to a normal alarm process or the like. If it is a stationary object (Y), the process proceeds to step S705. In step S705, the distance to the target determined to be a stationary object is calculated, and this distance is set to the set distance X ₂
It is said.

In step S706, it is checked whether or not the distance to the target captured by the inter-vehicle distance detecting device is larger than the set distance X ₂ . Here, if the target distance is larger than the distance X (Y), it is determined that the target is a roadside stationary object and is a no target in the vehicle lane. Then, in step S708, for example, a no-target flag is set. If the target distance is smaller than the set distance X ₂ (N), it is determined that the target is recognized in the vehicle lane, and step S707 is performed.
Then, for example, a flag for target recognition is set.

Then, the inter-vehicle distance detecting device uses the above-mentioned flags to perform a normal alarm process and the like. (Fifth Embodiment) In the first embodiment, when it is detected that the vehicle enters a curved road from a straight road by the guardrail or the roadside clutter, the inter-vehicle distance detection device uses a single fixed beam, I lost sight of the vehicle ahead,
There are cases where stationary objects on the vehicle lane on the curve cannot be detected.

Therefore, if the direction of the radio wave radar is changed to the direction in which the vehicle lane bends when the vehicle enters a curved road, the vehicle traveling ahead can be continuously detected when entering the curved road, and a stationary object on the curved road can be detected. Can also be detected. Hereinafter, an example in which the direction of the radio wave radar is changed when an approach to a curved road is detected will be described with reference to FIGS.
This will be described with reference to FIG.

In this embodiment, as shown in FIG.
When it is detected that the vehicle enters the curved road from the straight road indicated by A, the distance D from the vehicle to the guardrail or the roadside clutter is calculated, and the predetermined distance Y is set. Then, the vehicle advances to the position B in the figure and the distance D becomes the set distance Y.
When it becomes smaller, the distance D becomes the set distance Y,
Change the direction of the radio radar.

Therefore, the direction of the radio wave radar is as shown in FIG.
As shown in (b), the direction is changed to cover the own vehicle lane, and the inter-vehicle distance detection device can continuously detect a vehicle traveling ahead and is stationary on the own vehicle lane on the curved road. If there is an object, it can be detected immediately. This control may be performed after entering the curved road until the end of the curved road, but since the detection function may deteriorate due to malfunction etc., at the time of entering the curved road, a steering sensor or yaw rate sensor, etc. It is effective to apply correction by

When a steering sensor or a yaw rate sensor is used, as shown in FIG. 8 (b), when the vehicle is at a position C where the vehicle goes out of a curved road to a straight road, the radio wave radar follows the steering operation. It is possible that the vehicle may turn away from the vehicle lane and may not detect a target on the vehicle lane. Therefore, when the inter-vehicle distance detector stops detecting the guardrail or roadside clutter, or when the distance suddenly changes, or when the clutter level suddenly decreases, it is possible to drive the vehicle forward by adjusting the radio radar direction to the vehicle direction. Prevent undetected objects such as cars or stationary objects on the vehicle lane.

A method of changing the direction of the radio wave radar of the inter-vehicle distance detecting apparatus in this embodiment will be described with reference to the flowchart of FIG. In step S901, the distance to the target and the relative speed are detected by a normal method. In step S902, the curved road determination processing shown in FIG. 1 is performed, and the result is checked in step S903. As a result, if the straight road determination is made (N), the direction of the radio wave radar is set to the center in step S904.

When it is determined that the road is a curved road in step S903 (Y), the process proceeds to step S905 and a predetermined distance Y is set. Here, the set distance Y is determined by the vehicle speed or the curve R as shown in FIG. As shown here, when the vehicle speed or the curve R is large, the set distance Y is set to be long, and when the vehicle speed or the curve R is small, the set distance Y is shortened. The curve R can be obtained by using the map of the navigation system or by calculating the distance between vehicles.

In step S906, it is checked whether or not the distance to the guardrail or the roadside clutter detected during the determination of the curved road is smaller than the predetermined distance Y.
When the distance between the vehicle and the guardrail or the like is longer than the set distance Y (N), the process proceeds to step S904, and the direction of the radio wave radar is kept in the center. When the distance between the vehicle and the guardrail or the like becomes smaller than the predetermined distance Y (Y), the process proceeds to step S906, and it is checked whether or not the steering operation is being performed. Since the steering is not operated at the position A before entering the curved road from the straight road (N),
In step S908, the direction of the radio wave radar is changed. The vehicle at the position B in FIG. 8A is in a state where the direction of the radio wave radar is changed.

When the vehicle enters a curved road and the steering is operated, the process proceeds from Y in step S907 to step S90.
Proceed to 9. In step S909, the direction of the radio wave radar is corrected based on the steering amount and the vehicle speed. When the direction of the radio wave radar is corrected by the steering operation, as shown in FIG. 8B, the direction in which the radio wave radar is tilted with respect to the vehicle lane at the position C on the curved road before the straight road is shown. It will turn. However, there is a position immediately before point C in FIG. 8B where the distance to the guardrail or the like cannot be measured. At this time, in step S906 of FIG.
Therefore, the flow proceeds to step S904, the direction of the radio wave radar is set to the center, and the vehicle lane faces upward.

[0043]

According to the present invention, it is possible to obtain an inter-vehicle distance detecting device capable of detecting that a vehicle enters a curved road from a straight road. According to the present invention, it is possible to obtain an inter-vehicle distance detection device that can perform processing according to a curved road and can prevent a preceding vehicle from being lost or erroneously detecting an unnecessary reflection object on the road side as a target.

[Brief description of drawings]

FIG. 1 is a flowchart illustrating an operation of an inter-vehicle distance detection device according to a first embodiment of the present invention.

FIG. 2 is a graph showing the clutter level signal used in FIG.

FIG. 3 is a flowchart illustrating an operation of the inter-vehicle distance detecting device according to the second embodiment of the present invention.

FIG. 4 is a graph showing the relationship between the suppression time and the vehicle speed used in FIG.

FIG. 5 is a flowchart illustrating an operation of the inter-vehicle distance detecting device according to the third embodiment of the present invention.

FIG. 6 is a graph showing the relationship between the set distance used in FIG. 5 and the vehicle speed.

FIG. 7 is a flowchart illustrating an operation of the inter-vehicle distance detecting device according to the fourth embodiment of the present invention.

FIG. 8 is a plan view showing that the direction of the radio wave radar is changed in the fifth embodiment of the present invention.

FIG. 9 is a flowchart illustrating an operation of the inter-vehicle distance detecting device according to the fifth embodiment of the present invention.

10 is a graph showing the relationship between the set distance used in FIG. 9, the vehicle speed, and the curve R. FIG.

FIG. 11 is a block diagram showing a configuration of an inter-vehicle distance detection device.

FIG. 12 is a plan view showing a relationship between a curved road and a distance measuring area.

[Explanation of symbols]

 1 ... Inter-vehicle distance detection device 2 ... Processor 3 ... Antenna 4 ... Vehicle 5 ... Low-pass filter A, B, C, E, F ... Vehicle position D, G ... Distance measurement area

Claims (5)

[Claims] 1. An inter-vehicle distance detecting device using a radio wave radar, a means for detecting a guardrail, a means for detecting a clutter level, a means for detecting the guardrail by the guardrail detecting means, or a means for detecting the clutter level by the clutter level detecting means. By providing a means for determining that there is a curved road on the condition that the signal level has changed over time, the vehicle is traveling on the curved road or the vehicle is about to enter the curved road. An inter-vehicle distance detection device capable of detecting that. 2. A means for issuing an alarm according to the detected inter-vehicle distance, a means for detecting a stationary object, the curved road determination means for judging that there is a curved road, and the stationary object detection means for the stationary object. 2. The inter-vehicle distance detecting device according to claim 1, further comprising means for suppressing the alarm generated by the alarm generating means for a certain period of time when the alarm is detected. 3. The method according to claim 1, further comprising means for changing the detection distance of the radio wave radar to a distance determined by the vehicle speed when the curved road determination means determines that the vehicle is on a curved road.
The inter-vehicle distance detection device described. 4. A means for detecting a stationary object, and when the stationary object detection means detects a stationary object after the curved road determination means determines that the vehicle is a curved road, the detection distance of the radio wave radar is defined as the stationary object. 4. The inter-vehicle distance detecting device according to claim 3, further comprising means for changing the distance to a value equal to or less than the distance between the two. 5. A means for changing the direction of the radio wave radar so that the distance to an object on the road side becomes constant when the curved road judging means judges that the road is a curved road. The inter-vehicle distance detection device according to 1.