JP5146716B2 - Obstacle detection device for vehicles - Google Patents

Description

  The present invention relates to an obstacle detection device for a vehicle including a radar unit disposed at a front end portion of a vehicle, and more particularly, when the direction of a reference detection axis of a radar unit is deviated from an intended direction, the reference detection is performed. The configuration is such that the axis can be automatically corrected.

Conventionally, in a vehicle such as an automobile, a control technology for predicting a collision with a front obstacle (such as a preceding vehicle) and tightening a seat belt or operating a brake to avoid the collision is constant for the preceding vehicle. Is well known, and therefore, a radar unit having a millimeter wave radar or a laser radar is disposed forwardly on the front end portion of the vehicle, and this radar unit allows obstacles ahead. The position and relative speed of the vehicle can be detected, and the preceding vehicle can be recognized.

  By the way, in vehicles such as automobiles, in order to ensure that the performance of the radar unit is demonstrated and the control technology can be implemented with high accuracy, the radar unit is attached to the desired position (posture) of the front end part, Although the reference detection axis of the radar unit needs to be oriented in the intended direction, a relatively large force acts on the radar unit and its surroundings, for example, by causing a collision (light collision) after mounting the radar unit. Thus, although the radar unit is functioning, it is assumed that the direction of the reference detection axis of the radar unit deviates from the intended direction.

  Here, in Patent Document 1, a radio wave radar unit transmits radio waves in a state where a reference reflector is arranged at a predetermined position in front of the radio wave radar unit and a plurality of tires as radio wave absorbers are stacked in front of the radio wave radar unit.・ Receive, detect the position of the reference reflector, and adjust the reference detection axis of the radio radar unit via the adjustment bolt that attaches the radio radar unit to the bracket so that the position becomes the reference position of the radio radar unit A detection axis adjustment method is disclosed.

JP 2003-240837 A

  As described above, in a vehicle such as an automobile, a relatively large force acts on the radar unit or its periphery after the radar unit is mounted, for example, by causing a collision, so that the direction of the reference detection axis of the radar unit is changed. When deviating from the intended direction, even if the radar unit is functioning, the performance of the radar unit is surely exhibited and the control technology cannot be performed with high accuracy, and such control with problems in accuracy is performed unnecessarily. There are also concerns.

  In such a case, it is necessary to adjust the reference detection axis of the radar unit. Therefore, the detection axis adjustment method disclosed in Patent Document 1 can also be used, but the mounting portion (for example, the mounting bracket) of the radar unit may require repair. In any case, the adjustment operation of the reference detection axis of the radar unit, which involves personnel work, is very complicated. Note that if the personnel determine whether or not to adjust the reference detection axis of the radar unit, it may be overlooked if necessary. Even when the radar unit is first attached to a vehicle such as an automobile, a very complicated adjustment work for adjusting the reference detection axis is required.

  An object of the present invention is to automatically and reliably correct and adjust the reference detection axis when the direction of the reference detection axis of the radar unit arranged at the front end portion of the vehicle is deviated from the intended direction. It is possible to provide a vehicle obstacle detection device.

According to a first aspect of the present invention, there is provided a vehicle obstacle detection device including a radar unit that is disposed in a front end portion of a vehicle and detects obstacle information including an obstacle position in front of the vehicle, and an imaging unit that images the front of the vehicle. In the vehicle obstacle detection apparatus, the radar unit is configured to be able to detect obstacle information by reciprocating within a set angle (θre) about a vertical axis, and the imaging means is configured to detect the set angle of the radar unit. An obstacle in front of the vehicle having an imaging area wider than the detection area of the radar unit and having a first predetermined angle (θcm) larger than (θre) and imaged by the imaging means. the specific obstacle determination means for determining a closest obstacle to a predetermined reference sensing axis means as the specific obstacle, is determined by said radar unit detected obstacle in the specific obstacle determining means Based on the corresponding movement of the specific obstacle, the specific obstacle determination means for determining whether the detected obstacle is the specific obstacle, if the specific obstacle determination means is affirmative determination, the Based on image information of the specific obstacle imaged by the imaging means, an imaging obstacle position detection means for detecting the position of the specific obstacle, and a position of the specific obstacle detected by the imaging obstacle position detection means Specific obstacle position determination means for determining whether or not the position of the specific obstacle detected by the radar unit matches, and when the specific obstacle position determination means makes a negative determination, the imaging obstacle position detection means in sensed position correction permission determination to determine whether it is possible to correct the predetermined reference detection axis of the radar unit based on the position of the specific obstacle detected by the radar unit of the specific obstacle A stage, when a specific obstacle imaged is in the first predetermined angle (θcm) smaller second predetermined angle (θce) in said imaging means by said imaging means, said radar unit A correction failure determination means that makes a positive determination that correction of a predetermined reference detection axis is possible and makes a negative determination when it is not included, and a specific failure detected by the radar unit when the correction permission determination means makes a positive determination A reference detection axis correction unit that automatically corrects a predetermined reference detection axis of the radar unit so that the position of the object matches the position of the specific obstacle detected by the imaging obstacle position detection unit. It is characterized by that.

In this vehicle obstacle detection device, a radar unit (for example, a millimeter wave radar unit or a laser radar unit) is disposed forwardly on the front end portion of the vehicle, and the radar unit includes the position of the obstacle in front of the vehicle. Control that detects obstacle information, predicts a collision with a front obstacle (preceding vehicle, etc.) based on this obstacle information, tightens the seat belt, or activates the brake to avoid the collision In addition, it is possible to execute control to follow the preceding vehicle while maintaining a certain inter-vehicle distance.

The vehicle obstacle detection apparatus includes a radar unit, an imaging unit, a specific obstacle determination unit, a specific obstacle determination unit, an imaging obstacle position detection unit, a specific obstacle position determination unit, a correction availability determination unit, and a reference detection axis correction. The vehicle front is imaged by the imaging means, and the obstacle closest to the predetermined reference detection axis of the imaging means is determined as the specific obstacle by the specific obstacle determining means, The specific obstacle judging means judges whether or not the obstacle detected by the radar unit is a specific obstacle, and the image information of the specific obstacle ahead of the vehicle imaged by the imaging means by the imaging obstacle position detecting means. Based on this, the position of the specific obstacle is detected. Then, the specific obstacle position determination means determines whether the position of the specific obstacle detected by the imaging obstacle position detection means matches the position of the specific obstacle detected by the radar unit, and determines whether correction is possible. Means for determining whether or not the predetermined reference detection axis of the radar unit can be corrected, and the position of the specific obstacle does not coincide with the determination by the specific obstacle position determination means by the reference detection axis correction means. The predetermined reference detection axis of the radar unit is automatically corrected and adjusted so as to coincide with.

  The following configuration can be adopted as the dependent invention of claim 1.

  Alarm means that operates when the correction possibility determination means makes a negative determination is provided (claim 2).

  The radar unit is configured to reciprocate and scan the antenna within a set angle and to be reciprocally rotatable at an angle equal to or greater than the set angle, and the reference detection axis correction unit corrects the set angle. The reference detection axis is corrected (claim 3).

According to the vehicle obstacle detection device of the first aspect, in particular, the imaging unit images the front of the vehicle, and the specific obstacle determination unit determines the obstacle closest to the reference detection axis of the imaging unit as the specific obstacle. The specific obstacle judging means is based on the corresponding movement between the obstacle detected by the radar unit and the specific obstacle determined by the specific obstacle determining means, and the detected obstacle is the specific obstacle. The imaging obstacle position detection means detects the position of the specific obstacle based on the image information of the specific obstacle ahead of the vehicle imaged by the imaging means, and the specific obstacle position determination means Determining whether the position of the specific obstacle detected by the imaging obstacle position detecting means and the position of the specific obstacle detected by the radar unit match, that is, the direction of the reference detection axis of the radar unit is Whether or not it deviates from the initial direction And determining whether or not the correction possibility determination unit can correct the predetermined reference detection axis of the radar unit, and the reference detection axis correction unit receives the determination by the specific obstacle position determination unit and receives the specific obstacle. The reference detection axis of the radar unit can be automatically corrected and adjusted so as to match when the object positions do not match.

  Accordingly, in a vehicle such as an automobile equipped with this vehicle obstacle detection device, a relatively large force acts on the radar unit and its surroundings, for example, by causing a collision, and the direction of the reference detection axis of the radar unit is changed. If the radar unit is functioning when it deviates from the intended direction, there is no need to carry out complicated adjustment work for the reference detection axis, which involves conventional personnel work. Therefore, it is possible to perform the control with high accuracy by reliably exhibiting the performance of the radar unit.

  The processing by the imaging obstacle position detection means, the specific obstacle position determination means, the correction possibility determination means, and the reference detection axis correction means can be executed even when the vehicle is traveling, if there is a specific obstacle such as a preceding vehicle ahead of the vehicle. Therefore, it is possible to determine whether or not the direction of the reference detection axis of the radar unit is deviated from the intended direction at any time, periodically, or immediately after the collision occurs, and therefore the self-check function is excellent. When the direction of the reference detection axis is deviated from the intended direction, the reference detection axis can be corrected quickly, and therefore there is no possibility that the control having a problem in accuracy is performed unnecessarily. Is high and very reliable.

  Even when the radar unit is first installed in a vehicle such as an automobile, the direction of the reference detection axis is deviated from the intended direction after the radar unit is mounted without adjusting the reference detection axis so closely. In this case, since the reference detection axis can be automatically and reliably corrected and adjusted by causing the means to function, the load of mounting the radar unit on the vehicle (adjustment load of the reference detection axis) is reduced, and the radar The assembly of the unit can be remarkably improved.

Whether or not the detected obstacle is a specific obstacle imaged by the imaging means based on the corresponding movement between the obstacle detected by the radar unit and the specific obstacle determined by the specific obstacle determining means If the specific obstacle judging means makes a positive determination, the judgment by the specific obstacle position judging means is executed, so that the obstacle detected by the radar unit is imaged by the imaging means. If the obstacle is not a specific obstacle, the obstacle detected by the radar unit is prevented by correcting the reference detection axis that is mistakenly recognized by preventing the determination by the specific obstacle position determination means. When the object is a specific obstacle imaged by the imaging means, accurate recognition of the reference detection axis and correct correction of the reference detection axis when the direction of the reference detection axis is deviated from the intended direction are performed. It can be to be.

A correction enable / disable determining means for determining whether or not the reference detection axis can be corrected based on the position of the specific obstacle detected by the imaging obstacle position detecting means and the position of the specific obstacle detected by the radar unit; When the correction possibility determination means makes a positive determination, correction by the reference detection axis correction means is executed, so that when the reference detection axis cannot be corrected, the correction is prevented from being performed wastefully, Only when the detection axis can be corrected, the correction can be surely executed.
Correction-possibility determining means, when a specific obstacle taken by the imaging means is in the first predetermined angle (θcm) smaller second predetermined angle (θce) in the image pickup means, a predetermined radar units Since the affirmative determination is made that the reference detection axis can be corrected, and a negative determination is made when the reference detection axis is not entered, the predetermined range corresponding to the position of the specific obstacle is set in advance in consideration of the correction performance of the radar unit itself. Thus, it is possible to reliably determine whether or not the reference detection axis can be corrected by the correction possibility determination unit.

  According to the vehicle obstacle detection device of the second aspect, since the alarm means that operates when the correction possibility determination means makes a negative determination is provided, the vehicle obstacle detection device has failed based on the alarm. Can recognize and deal with it.

Vehicle obstacle detection device of the present invention includes a radar unit is disposed on the front end portion of the vehicle detects an obstacle information including the location of the vehicle in front of the obstacle, and an imaging means for imaging ahead of the vehicle, The radar unit is configured to reciprocate within a set angle (θre) around the vertical axis so as to detect obstacle information, and the imaging means has a first predetermined angle larger than the set angle (θre) of the radar unit. An obstacle that has an imaging area wider than the detection area of the radar unit, and is an obstacle in front of the vehicle imaged by the imaging means and closest to a predetermined reference detection axis of the imaging means. the specific obstacle determination means for determining as a specific obstacle, on the basis of the corresponding movement of the specific obstacle is determined by the specific obstacle determining means and the obstacle detected by the radar unit, the sensed disabled A specific obstacle judging means for judging whether or not the obstacle is a specific obstacle, and when the specific obstacle judging means makes an affirmative decision, the specific obstacle is based on the image information of the specific obstacle imaged by the imaging means. An imaging obstacle position detection means for detecting the position of the imaging obstacle, and a specification for determining whether or not the position of the specific obstacle detected by the imaging obstacle position detection means matches the position of the specific obstacle detected by the radar unit When the obstacle position determination means and the specific obstacle position determination means make a negative determination, based on the position of the specific obstacle detected by the imaging obstacle position detection means and the position of the specific obstacle detected by the radar unit Correction possibility determination means for determining whether or not a predetermined reference detection axis of the radar unit can be corrected, wherein the specific obstacle imaged by the imaging means is smaller than a first predetermined angle (θcm) of the imaging means. Correctability determination means for making a positive determination that the predetermined reference detection axis of the radar unit can be corrected when it is within the second predetermined angle (θce) , and making a negative determination if it is not , When the correction enable / disable determining means makes an affirmative determination, a predetermined reference of the radar unit is set so that the position of the specific obstacle detected by the radar unit matches the position of the specific obstacle detected by the imaging obstacle position detecting means. And a reference detection axis correction unit that automatically corrects the detection axis.

  As shown in FIGS. 1 to 3, the vehicle obstacle detection device 1 is mounted on an automobile V, and is disposed forwardly at the center in the vehicle width direction of the front end portion Va and includes an obstacle position in front of the vehicle. A radar unit 2 for detecting object information, a camera unit 3 that is arranged forward in the vehicle width direction center portion of the front end of the vehicle interior of the roof Vd and that images the front of the vehicle, and a display and lamp that are alarm means An alarm device 4, a radar unit 2, a camera unit 3, and a control unit 5 (including a CPU 5a, a ROM 5b, and a RAM 5c) electrically connected to the alarm device 4 are provided.

  A front grill Vb is provided at the vehicle width direction central portion of the front end portion Va, an emblem Vc is attached to the central portion of the front grill Vb, and the radar unit 2 is disposed immediately behind the emblem Vc. The emblem Vc is excellent in radio wave transmission so as not to attenuate radio waves transmitted / received by the radar unit 2.

  As shown in FIGS. 3 and 4, the radar unit 2 includes a transmission / reception movable unit 10, a scanning drive unit 15, an analog circuit 20, a processing unit 21, and an interface 22 (IF 22). The IF 22 is connected to the control unit 5. ing. The transmission / reception movable unit 10 includes a millimeter wave transmitter / receiver 11 for transmitting / receiving millimeter waves and an antenna 12 for receiving millimeter waves. The millimeter wave transmitter / receiver 11 and the antenna 12 are integrally rotated around a vertical axis. It is comprised so that rotation is possible.

  The scanning drive unit 15 is a mechanism for reciprocatingly rotating the transmission / reception movable unit 10 within the set angle θre, and the center line of the set angle θre serves as the reference detection axis BAr of the radar unit 2 and is usually directed forward. ing. The scanning drive unit 15 includes, for example, an electric motor 16, a drive circuit 17, and an encoder 18, and the processing unit 21 receives a signal from the encoder 18, and the rotation angle of the transmission / reception movable unit 10 determines the reference detection axis BAr. The electric motor 16 is driven and controlled via the drive circuit 17 so that the set angle θre is the center.

  The processing unit 21 controls the electric motor 16, and inputs information regarding transmission and reception of millimeter waves from the millimeter wave transmitter / receiver 11 via the analog circuit 20, for example, AD conversion of a beat signal from the millimeter wave transmitter / receiver 11 Then, frequency analysis is performed, and the position (direction, distance) and relative speed, which are obstacle information of the obstacle ahead, are calculated. This obstacle information is output from the IF 22 to the control unit 5, and the control unit 5 leaves a collision with the obstacle based on this obstacle information, tightens the seat belt, or operates the brake to make the collision. Control to avoid or control to follow the vehicle while maintaining a certain distance between the preceding vehicles.

  Here, as shown in FIG. 4, the radar unit 2 scans the movable transmitting / receiving unit 10 (millimeter wave transceiver 11, antenna 12) by reciprocatingly rotating within the set angle θre, and an angle θrm that is equal to or larger than the set angle θre. It is comprised so that reciprocating rotation is possible.

As shown in FIG. 5, it is assumed that the reference detection axis BAc of the camera unit 3 is directed forward and does not deviate from this intended direction. Usually, the reference detection axis BAr of the radar unit 2 is directed in the forward direction and coincides with the reference detection axis BAc of the camera unit 3. The camera unit 3 has a first predetermined angle θcm larger than the set angle θre of the radar unit 2, and has a wider imaging area than the detection area of the radar unit 2.

  Here, as shown in FIG. 6, although the radar unit 2 is functioning due to a relatively large force acting on the radar unit 2 and its surroundings by, for example, causing a collision (light collision), the radar unit Assume that the direction of the second reference detection axis BAr is shifted by θ1 from the front side to the left side. In this case, even if the obstacle SO is detected by the radar unit 2, the position of the obstacle SO is erroneously detected at a position indicated by a virtual line shifted by θ1 to the right side from the actual position indicated by the solid line.

  Therefore, the vehicle obstacle detection device 1 of the present invention automatically analyzes whether or not the direction of the reference detection axis BAr of the radar unit 2 has deviated from the intended direction. When the reference detection axis BAr can be corrected so that the direction of the target is the desired direction, the correction is automatically performed, and the processing for that is performed mainly by the control unit 5. This is as shown in the flowchart of FIG.

  As shown in FIG. 7, the process executed by the control unit 5 is started at any time or periodically or immediately after a collision occurs. First, whether or not information can be normally received from the radar unit 2 (S1). It is determined whether or not information can be normally received from the camera unit 3 (S2). If S1; No or S2; No, the pre-crash safety system that executes the control is disabled (S20). Subsequently, the alarm process (S21) is executed, the alarm device 4 is activated, and the alarm device 4 displays a notification that the vehicle obstacle detection device 1 (radar unit 2 or camera unit 3) has failed, finish.

  In the case of S1; Yes, S2; Yes, based on the image information from the camera unit 3, it is determined whether or not a candidate (obstacle) for the specific obstacle SO as shown in FIGS. In the case of S3), S3; Yes, the specific obstacle SO is determined (S4). As this specific obstacle SO, one obstacle close to the reference detection axis BAc of the camera unit 3 is determined. For example, even when a plurality of obstacles that are candidates for the specific obstacle SO exist, It is preferable to determine the obstacle closest to the reference detection axis BAc from among the obstacles.

  Thus, even when the direction of the reference detection axis BAr of the radar unit 2 is deviated from the intended direction to the left or right, there is a possibility that the radar unit 2 can detect the specific obstacle SO imaged by the camera unit 3. Next, a specific obstacle determination process (S5) for determining whether or not the obstacle detected by the radar unit 2 is the specific obstacle SO imaged by the camera unit 3 is executed. S3: If No, the process proceeds to S15.

  That is, this specific obstacle determination process is a process for determining whether or not the specific obstacle SO imaged by the camera unit 3 and the specific obstacle SO detected by the radar unit 2 are the same object. For example, an obstacle that may become a specific obstacle SO is detected by the radar unit 2, and the obstacle and the specific obstacle SO detected from the camera unit 3 change corresponding movements (for example, for a minute time). In the case of making a corresponding movement, it is determined that the specific obstacle SO imaged by the camera unit 3 and the specific obstacle SO detected by the radar unit 2 are the same object.

  If the specific obstacle SO cannot be determined by the radar unit 2 by the specific obstacle determination process in S5 (S6; No), the process proceeds to S20, and if it can be determined (S6; Yes), then the radar unit 2 specifies the specific obstacle SO. The position (direction) of the obstacle SO is read (S7), and then the position (direction) of the specific obstacle SO is detected based on the image information of the specific obstacle SO captured at the same time by the camera unit 3. (S8). In S8, for example, the distance of the specific obstacle SO from the radar unit 2 is read, and based on the distance of the specific obstacle SO and the image information from the camera unit 3, the actual obstacle SO is actually detected with respect to the radar unit 2. The direction, that is, the direction of the actual reference detection axis BAr of the radar unit 2 is calculated.

  Next, in the specific obstacle position determination process of S9, the position (direction) of the specific obstacle SO detected in S8 and the position (direction) of the specific obstacle SO detected by the radar unit 2 and read in S7 are determined. It is determined whether or not they match, that is, whether or not the reference detection axis BAr of the radar unit 2 and the reference detection axis BAc of the camera unit 3 match, and the position of the specific obstacle SO matches as shown in FIG. If so, the process proceeds to S15. On the other hand, if the position of the specific obstacle SO does not match as shown in FIG. 6, then the position (direction) of the specific obstacle SO detected in S8 and the specific obstacle detected by the radar unit 2 are used. Based on the position (direction) of SO, a correction possibility determination process (S11) for determining whether or not the reference detection axis BAr of the radar unit 2 can be corrected is executed.

The correction permission determination process is affirmative determination when a specific obstacle SO captured by the camera unit 3 is within the first predetermined angle θcm smaller second predetermined angle θce than (the predetermined range), If it does not enter, it is configured to make a negative determination, taking into account the correction performance of the radar unit 2 itself (an angle θ rm larger than the set angle θre of the radar unit 2), and the second corresponding to the position of the specific obstacle SO By setting the predetermined angle θce of 2 in advance, it is reliably determined whether or not the reference detection axis BAr of the radar unit 2 can be corrected.

  Next, when the correction of the reference detection axis BAr is impossible (S12; No), the process proceeds to S20, and when the correction of the reference detection axis BAr is possible (S12; Yes), the specific fault detected by the radar unit 2 is detected. Correction of the reference detection axis BAr so that the object SO coincides with the position of the specific obstacle SO detected in S8, that is, the reference detection axis BAr coincides with the reference detection axis BAc of the camera unit 3 (S13). Is done. In this case, a motor control command is output to the processing unit 21 of the radar unit 2, and the electric motor 16 is driven and controlled by the processing unit 21 based on the command, so that the set angle θre of the transmission / reception movable unit 10 is within the angle θrm. The reference detection axis BAr is corrected by being corrected to be shifted.

  Next, using the same determination routine as in S9, it is determined whether or not the correction is completed (S14). If S14; No, the process returns to S11. On the other hand, in the case of S14; Yes, the state shown in FIG. 6 is changed to the state shown in FIG. 5, but the operation of the pre-crash safety system is permitted (S15) including S3; No, S10; To do. S4 is a specific obstacle determination means, S5 is a specific obstacle determination means, S8 is an imaging obstacle position detection means, S9 is a specific obstacle position determination means, S11 is a correction possibility determination means, and S13 is a reference detection axis correction means. , Respectively.

The vehicle obstacle detection device 1 described above has the following effects.
The camera unit 3 images the front of the vehicle, detects the position of the specific obstacle SO based on the image information of the specific obstacle SO in front of the vehicle imaged by the camera unit 3, and detects the detected specific obstacle SO. It is determined whether or not the position of the specific obstacle SO detected by the radar unit 2 coincides, that is, whether or not the direction of the reference detection axis BAr of the radar unit 2 is deviated from the intended direction. Thus, the reference detection axis BAr of the radar unit 2 can be automatically corrected and adjusted so as to match when the position of the specific obstacle SO does not match.

  Accordingly, in the automobile V equipped with the vehicle obstacle detection device 1, a relatively large force acts on the radar unit 2 and its surroundings by, for example, causing a collision, so that the reference detection axis BAr of the radar unit 2 When the direction deviates from the intended direction, when the radar unit 2 is functioning, it is not necessary to perform the complicated adjustment work of the reference detection axis BAr that involves conventional personnel work, and the reference detection axis BAr is It is possible to automatically and reliably correct and adjust. Therefore, the performance of the radar unit 2 can be reliably exhibited and the control can be performed with high accuracy.

  Since such imaging obstacle position detection, specific obstacle position determination, and reference detection axis correction can be executed even when the vehicle is traveling, if there is a specific obstacle SO such as a preceding vehicle ahead of the vehicle, the reference detection of the radar unit 2 is possible. Whether the direction of the axis BAr is deviated from the intended direction can be determined at any time, periodically, or immediately after the collision occurs, and therefore the self-check function is excellent, and the reference detection axis BAr When the direction is deviated from the intended direction, the reference detection axis BAr can be corrected quickly, and therefore, there is no possibility that the control having a problem in accuracy is performed unnecessarily. As a result, the convenience and reliability are high. It becomes very excellent in nature.

  In addition, when the radar unit 2 is first attached to the vehicle V, the direction of the reference detection axis BAr is shifted from the intended direction after the radar unit 2 is mounted without adjusting the reference detection axis BAr so closely. In this case, the reference detection axis BAr can be automatically and reliably corrected and adjusted, so that the load of mounting the radar unit 2 on the vehicle V (adjustment load of the reference detection axis BAr) can be reduced, and the radar unit 2 can be remarkably improved.

  It is determined whether the obstacle detected by the radar unit 2 is the specific obstacle SO imaged by the camera unit 3, and if the determination is affirmative, the specific obstacle position determination process is executed. When the detected obstacle is not the specific obstacle SO imaged by the camera unit 3, the specific obstacle position determination process is not executed, and erroneous recognition and correction of the reference detection axis BAr are performed. When the obstacle detected by the radar unit 2 is the specific obstacle SO imaged by the camera unit 3, the correct recognition of the reference detection axis BAr and the direction of the reference detection axis BAr are determined as desired. It is possible to correct the reference detection axis BAr when it is deviated from the direction.

  Based on the position of the specific obstacle SO detected from the camera unit 3 and the position of the specific obstacle SO detected by the radar unit 2, it is determined whether or not the reference detection axis BAr can be corrected, and an affirmative determination is made. In this case, since the correction of the reference detection axis BAr is performed, when the correction of the reference detection axis BAr is impossible, the correction is prevented from being performed wastefully, and the correction of the reference detection axis BAr is possible. Only, the alarm device 4 is provided that operates when the correction is reliably executed and it is determined that the correction of the reference detection axis BAr is impossible. Therefore, based on the alarm, the obstacle detection device for a vehicle is provided. It is possible to recognize and deal with the fact that 1 is out of order.

The correction possibility determination process makes an affirmative determination when the specific obstacle SO within the predetermined angle θce (within a predetermined range) imaged by the camera unit 3 can be detected by the radar unit 2, and makes a negative determination when the specific obstacle SO cannot be detected. In consideration of the correction performance of the unit 2 itself, the second predetermined angle θce corresponding to the position of the specific obstacle SO is set in advance, thereby reliably determining whether or not the reference detection axis BAr can be corrected. Can do. The radar unit 2 is configured to reciprocate and scan the antenna 12 within a set angle θre, and to reciprocate at an angle θrm that is equal to or greater than the set angle θre. By correcting the set angle θre, the reference detection axis BAr Therefore, when the direction of the reference detection axis BAr is deviated from the intended direction, the reference detection axis BAr can be reliably corrected.

  In the second embodiment, the processing from after S4 in FIG. 7 to before S10 performed by the control unit 5 is shown more specifically. However, the distance and direction of the obstacle can be detected based on the image information of the camera unit 3.

  As shown in FIG. 8, in this process, after S4, it is first determined whether or not the distance from the camera unit 3 to the specific obstacle SO can be detected (S30). If S30; No, the process proceeds to S20. S30: If Yes, the distance is detected (S31). Next, it is determined whether or not the direction of the specific obstacle SO can be detected from the camera unit 3 (S32). If S32; No, the process proceeds to S20. If S32; Yes, the direction is detected (S33). ).

  Next, it is determined whether or not an obstacle that may become the specific obstacle SO can be detected from the radar unit 2 (S34). If S34; No, the process proceeds to S20, and if S34; Yes, the obstacle is detected. The distance and direction are detected (S35, S36), and then the specific obstacle determination process (S37) of S37 is executed based on the detection information of S31, S32, S35, S36.

  In this specific obstacle determination process, for example, as in the first embodiment, it is determined whether or not the specific obstacle SO detected from the camera unit 3 and the obstacle detected by the radar unit 2 move correspondingly. When the corresponding movement is made, an affirmative determination is made that the specific obstacle SO imaged by the camera unit 3 and the specific obstacle SO detected by the radar unit 2 are the same, and then the process proceeds to S10.

  Instead of the radar unit 2, a non-mechanical scanning electronic radar unit may be employed. This electronic radar unit has a plurality of antennas arranged in parallel in the vehicle width direction. For example, the electronic radar unit detects the direction of an obstacle based on the phase difference of received signals (radio waves, radar) between adjacent antennas. is there.

  When this electronic radar unit is employed, when the reference detection axis BAr is corrected, a movable portion is provided that is attached with a plurality of antennas and is rotatable about the vertical axis, and the reference detection axis BAr is the camera unit 3. The reference detection axis BAr can be corrected and adjusted by automatically rotating the movable part so as to coincide with the reference detection axis BAc. Alternatively, even if a plurality of antennas are fixedly attached, the reference detection axis BAr can be corrected internally (in terms of processing) of the electronic radar unit.

  In addition, various changes and additions can be made without departing from the spirit of the present invention, and the present invention can be applied to various vehicles other than automobiles.

It is a perspective view of the motor vehicle equipped with the obstacle detection apparatus for vehicles. It is a block diagram of the configuration of the vehicle obstacle detection device. It is a block diagram of the configuration of the radar unit. It is a figure of the principal part of a radar unit. It is a top view which shows the detection area | region of a radar unit (at the time of normal), a reference | standard detection axis | shaft, etc. FIG. It is a top view which shows the detection area, a reference | standard detection axis | shaft, etc. of a radar unit (at the time of deviation | shift). It is a flowchart of the process which the control unit of Example 1 performs. It is a flowchart of the process which the control unit of Example 2 performs.

V Car Va Front end part 1 Vehicle obstacle detection device 2 Radar unit 3 Camera unit 4 Alarm device 5 Control unit 12 Antenna BAr Reference detection axis SO Specific obstacle

Claims (2)

In a vehicle obstacle detection device including a radar unit that is arranged at a front end portion of a vehicle and detects obstacle information including the position of an obstacle in front of the vehicle, and an imaging unit that images the front of the vehicle,
The radar unit is configured to detect obstacle information by reciprocating within a set angle (θre) around a vertical axis,
The imaging means has a first imaging angle (θcm) larger than a setting angle (θre) of the radar unit, and has a wider imaging area than the detection area of the radar unit,
A specific obstacle determining means for determining an obstacle in front of a vehicle imaged by the imaging means and closest to a predetermined reference detection axis of the imaging means as a specific obstacle;
Based on the corresponding movement between the obstacle detected by the radar unit and the specific obstacle determined by the specific obstacle determining means, it is determined whether or not the detected obstacle is the specific obstacle. Specific obstacle judgment means,
When the specific obstacle determination means makes an affirmative determination, an imaging obstacle position detection means that detects the position of the specific obstacle based on image information of the specific obstacle imaged by the imaging means;
Specific obstacle position determination means for determining whether the position of the specific obstacle detected by the imaging obstacle position detection means matches the position of the specific obstacle detected by the radar unit;
If the specific obstacle position determination means makes a negative determination, the radar unit is based on the position of the specific obstacle detected by the imaging obstacle position detection means and the position of the specific obstacle detected by the radar unit. A correction enable / disable determining means for determining whether or not the predetermined reference detection axis can be corrected, wherein the specific obstacle imaged by the imaging means is smaller than a first predetermined angle (θcm) of the imaging means . if the it is within a predetermined angle (θce) within a predetermined affirmative determination that can be corrected reference sensing axis, correction-possibility determining means that a negative determination for when not in said radar unit,
When the correction possibility determination means makes a positive determination, the position of the specific obstacle detected by the radar unit matches the position of the specific obstacle detected by the imaging obstacle position detection means. A reference detection axis correction means for automatically correcting a predetermined reference detection axis;
An obstacle detection device for a vehicle, comprising:   The vehicle obstacle detection device according to claim 1, further comprising an alarm unit that operates when the correction possibility determination unit makes a negative determination.