JP2020106511A - Method and system for automatic adjustment of sensor for automobile - Google Patents

Abstract

To provide a method and a system for automatic adjustment of a sensor for an automobile.SOLUTION: The method for automatic adjustment of a sensor for an automobile according to the present invention includes the steps of: arranging a sensor for an automobile in the body of the automobile; determining whether there is a request for adjustment on the basis of the situation of travel environments of the body of the automobile; and adjusting the attitude of the sensor for an automobile in responce to the request for adjustment. There is also provided a system for automatic adjustment of the sensor for an automobile.SELECTED DRAWING: Figure 4

Description

The present invention relates to an automatic vehicular sensor adjustment method and system for an automobile.

An unmanned vehicle is an automated power vehicle, also called an autonomous vehicle or robot car. Since it is an automated vehicle, it is possible to detect the traveling environment and perform navigation without human operation.

However, one of the necessary conditions for operating an unmanned vehicle is a sensor. Since all of these sensors are generally fixed type sensors, their heights and angles (including tilt angle and rotation angle) cannot be adjusted, and the detection range of each sensor is limited.

In order to solve the above-mentioned problem of the limit of the detection range of the sensor, in the related art, a plurality of fixed sensors are installed at different positions of the vehicle body to supplement the detection range of a single sensor. When the sensor is mounted at a low position on the vehicle body, it is effective in places such as an underpass, a tunnel, or a ditch, but the sensor is shielded by surrounding objects and a wide field of view cannot be secured. When the sensor is installed at a high position on the vehicle body, the field of view is widened, but the vehicle is unable to enter a specific place (underpass, tunnel, ditch, etc.) due to restrictions on the height of the traveling environment. Furthermore, it is necessary to change the monitoring position of the fixed sensor according to the change of the terrain (hills and curves).

As described above, there are various driving environment situations on the road on which the vehicle travels. For example, there are height restrictions on the driving environment, speed restrictions on the road, speed of the vehicle, whether there is a change in the slope of the road, there is an intersection or a curve in the front, there is an obstacle in front, or the side with the sensor is blocked. The detection range of the fixed type sensor is affected by these various driving environment conditions, and the detection range of the fixed type sensor cannot be covered, making it impossible to detect the target object in a specific distance range. It was The installation height and angle of the fixed type sensor cannot be adjusted according to the conditions of these various driving environments, and the monitoring position of the fixed type sensor cannot be changed, so the demand can be met even if multiple fixed type sensors are installed. In addition, the detection range of the fixed type sensor cannot be adjusted according to the change of the driving environment to cover the target object in the specific distance range.

Therefore, the present inventor thought that the above-mentioned drawbacks could be ameliorated and, as a result of intensive studies, came to the proposal of the present invention which effectively ameliorate the above-mentioned problems by rational design.

The present invention has been made in view of such conventional problems. In order to solve the above problems, the present invention mainly aims to provide a method and system for automatically adjusting a sensor for an automobile. In other words, the attitude of the vehicle sensor is adjusted by issuing adjustment requests corresponding to various driving environment conditions, and the fixed sensor cannot adjust the attitude, which limits the field of view and space. Solve the problem.

In order to solve the above-mentioned problems, an automobile sensor automatic adjustment method according to an aspect of the present invention is a step of arranging an automobile sensor having an attitude on a vehicle body, wherein the attitude of the automobile sensor is an automotive sensor with respect to the vehicle body. Of the vehicle sensor relative to the vehicle body, including the height and position of the vehicle sensor relative to the vehicle body, and is adjusted based on the driving environment of the vehicle body. A step of determining whether or not there is a request, wherein the driving environment situation includes a single event or a combination of multiple events, and the attitude of the vehicle sensor is adjusted based on the adjustment request. And steps.

Another aspect of the present invention is a sensor automatic adjustment system for an automobile. This system is applied to a vehicle body, and an automobile sensor automatic adjustment system includes an automobile sensor, a control unit, and a posture adjustment mechanism. The vehicle sensor has a posture, and the posture of the vehicle sensor is defined by one of the distance, the tilt angle, and the rotation angle of the vehicle sensor with respect to the vehicle body. The distance of the vehicle sensor with respect to the vehicle body includes the height and position of the vehicle sensor with respect to the vehicle body. The control unit is connected to the vehicle sensor, the control unit determines whether there is an adjustment request based on the situation of the driving environment, and the control unit causes the vehicle sensor automatic adjustment method to be determined based on the adjustment request. And the corresponding control signal is output. The driving environment situation includes a single event or a combination of multiple events. The attitude adjusting mechanism is connected to the vehicle sensor and the control unit, and the attitude adjusting mechanism adjusts the attitude of the vehicle sensor based on the control signal of the control unit.

As described above, the vehicle sensor automatic adjustment method and system according to the present invention adjust the attitude of the vehicle sensor based on the corresponding adjustment request according to the situation of different traveling environments, and set the target in a specific distance range. An object is detected, and a situation where the detection range is shielded by the vehicle body or a shield is avoided.

1 is a schematic view showing an automatic sensor adjustment system for a vehicle according to an embodiment of the present invention. FIG. 1 is a schematic diagram in which an automobile sensor automatic adjustment system according to an embodiment of the present invention is mounted on a vehicle body. It is a schematic diagram showing a posture adjustment mechanism concerning one embodiment of the present invention. FIG. 5 is a schematic view of an embodiment in which the height of the vehicle sensor with respect to the vehicle body is adjusted by the attitude adjusting mechanism according to the embodiment of the present invention. FIG. 5 is a schematic view of adjusting the inclination angle of the vehicle sensor with respect to the vehicle body by the attitude adjusting mechanism according to the embodiment of the present invention. 3 is a flowchart showing an automobile sensor automatic adjustment method according to an embodiment of the present invention. FIG. 3 is a schematic view of a traveling environment situation that the vehicle body of the present invention encounters while driving. 6 is a flowchart of an embodiment for adjusting the height of the vehicle sensor in the vehicle sensor automatic adjustment method according to the embodiment of the present invention. 6 is a flowchart of an embodiment for adjusting the height of the vehicle sensor in the vehicle sensor automatic adjustment method according to the embodiment of the present invention. 6 is a flowchart of an embodiment for adjusting the height of the vehicle sensor in the vehicle sensor automatic adjustment method according to the embodiment of the present invention. 6 is a flowchart for adjusting an inclination angle of an automobile sensor in an automobile sensor automatic adjustment method according to an embodiment of the present invention. 6 is a flowchart for adjusting an inclination angle of an automobile sensor in an automobile sensor automatic adjustment method according to an embodiment of the present invention. 6 is a flowchart for adjusting an inclination angle of an automobile sensor in an automobile sensor automatic adjustment method according to an embodiment of the present invention. 3 is a flowchart for adjusting a rotation angle of a vehicle sensor of an automobile sensor automatic adjustment method according to an embodiment of the present invention. FIG. 3 is a schematic diagram when a situation of a traveling environment of a vehicle body according to an embodiment of the present invention is a phenomenon of lateral adjustment. FIG. 9B is a schematic diagram for adjusting the rotation angle of the vehicle sensor with respect to the vehicle body shown in FIG. 9A. FIG. 9B is a schematic view showing an embodiment for adjusting the position of the sensor with respect to the vehicle body shown in FIG. 9A. It is a schematic diagram showing a sensor automatic adjustment system for vehicles concerning other embodiments of the present invention. 9 is a flowchart showing another embodiment of the vehicle sensor automatic adjustment method shown in FIG. 4.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. The present invention is not limited to the embodiments described below.
Incidentally, in the description of each embodiment, when one member is described as “above/above” or “below/below” another member, it may be directly or indirectly above or below the other member. The state of being located in the position of the other part, which includes the case where other members are installed therebetween. The so-called "direct" means a state in which other intermediate members are not installed therebetween. "Up/Up", "Down/Down", "Left/Left", "Right/Right", "Front/Front", "Back/Rear", "X Axis", "Y Axis", or " Descriptions such as "Z-axis" are described with reference to the drawings, but include other possible turns. The members are different from the so-called "first" and "second", and these members are not limited by such a term. Further, for the sake of easy understanding, the thickness and size of each member in the drawings are exaggerated, omitted, or schematically indicated, and the size of each member is not completely the same as the actual size.

FIG. 1 is a schematic diagram showing a sensor automatic adjustment system for a vehicle according to an embodiment of the present invention. FIG. 2 is a schematic view of a vehicle automatic sensor adjustment system according to an embodiment of the present invention. The vehicle sensor automatic adjustment system 100 according to the present embodiment is installed, for example, on the vehicle roof 52 of the vehicle body 50. In another embodiment, not shown, the vehicle sensor 110 is installed on the side of the vehicle body 50 or at another position according to actual demand. The vehicle sensor automatic adjustment system 100 includes a vehicle sensor (vehicular sensor) 110, a posture adjustment mechanism 120, and a control unit 130. The attitude adjustment mechanism 120 is connected to the vehicle sensor 110 and the control unit 130, and the attitude adjustment mechanism 120 is located between the vehicle sensor 110 and the vehicle body 50. The control unit 130 is implemented by hardware (eg, processor, host computer), software (eg, program instructions executed by processor), or a combination thereof (see FIGS. 1 and 2).

In the present embodiment, the vehicle sensor 110 is, for example, a rider (Light Detection And Ranging, LiDAR), and the vehicle sensor 110 includes a sensing portion 112. When the vehicle sensor 110 is a rider, the laser light of the vehicle sensor 110 passes through the detection unit 112 and is applied to the target object. The distance to the target object is measured by measuring the time interval of the transmitted and received signals. To calculate. The vehicle sensor 110 has a posture P, and the posture P of the vehicle sensor 110 is defined by one of a distance, a tilt angle, and a rotation angle of the vehicle sensor 110 with respect to the vehicle body 50. The distance of the vehicle sensor 110 with respect to the vehicle body 50 includes the height and position of the vehicle sensor 110 with respect to the vehicle body 50, and the attitude P of the vehicle sensor 110 is related to the detected region of the vehicle sensor 110.

Incidentally, the term "height of the vehicle sensor 110 with respect to the vehicle body 50" used herein refers to the installation height of the vehicle sensor 110, that is, when the height of the vehicle sensor 110 with respect to the adjusted vehicle body 50 is adjusted. Indicates that the vertical distance of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted. In the example of FIG. 2, since the automobile sensor 110 is installed at the position of the automobile roof 52, the distance from the reference line BL of the automobile sensor 110 to the automobile roof 52 of the automobile body 50 is set at the height of the automobile body 50. The sum is the installation height of the vehicle sensor 110, and the height of the vehicle body 50 refers to the distance from the ground to the highest point of the vehicle body 50 (the vehicle roof in FIG. 2). The reference line BL of the vehicle sensor 110 is set so as to pass through the detection unit 112 of the vehicle sensor 110. In an embodiment not shown, the vehicle sensor 110 is installed on the side of the vehicle body 50, and the distance from the height of the vehicle body 50 to the vehicle roof 52 of the vehicle body 50 from the reference line BL of the vehicle sensor 110. The drawn value becomes the installation height of the automobile sensor 110.

The term “position of the vehicle sensor 110 with respect to the vehicle body 50 ”as used herein refers to a position where the vehicle sensor 110 is installed on the vehicle body 50, that is, the position of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted. Means adjusting the horizontal distance of the vehicle sensor 110 with respect to the vehicle body 50. 2, the automobile sensor 110 is installed at the position of the automobile roof 52, and in the two-dimensional plane formed by the X axis and the Y axis, the automobile sensor 110 (forward movement, backward movement, left movement, right movement). The position of the vehicle sensor 110 on the vehicle roof 52 is adjusted by moving (including linear movement such as movement and diagonal directions). Further, the above-mentioned depiction of “X-axis”, “Y-axis”, “Z-axis” and the like will be described by way of example with reference to the drawings, but the present invention is also limited to other possible direction changes. It doesn't let you.

The term “inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 ”refers to a narrow angle formed between the reference line BL of the vehicle sensor 110 and the reference reference of the vehicle body 50, and In the case of 2 as an example, the reference standard is the vehicle length direction L, and the vehicle length direction L is defined as a direction formed along the X axis on both opposite sides (for example, front and rear) of the vehicle body 50. Further, the extending direction of the axis C of the automobile sensor 110 passes through the vehicle length direction L and is parallel to the Z axis. The inclination angle of the vehicle sensor 110 is an angle formed between the reference line BL of the vehicle sensor 110 and the vehicle longitudinal direction L of the vehicle body 50, and, as shown in FIG. 2, the Z axis and the X axis. On the two-dimensional plane formed by, the reference line BL of the vehicle sensor 110 makes an angle with the vehicle longitudinal direction L of the vehicle body 50. For example, the inclination angle of the vehicle sensor 110 shown in FIG. 2 is 0 degree, that is, the reference line BL is parallel to the vehicle longitudinal direction L of the vehicle body 50. The description of the above-mentioned "X-axis", "Y-axis", "Z-axis", etc. will be described with reference to the drawings by way of example, but the present invention should be understood to include other possible direction changes. It is not limited to this.

Further, the term "rotation angle of the vehicle sensor 110 with respect to the vehicle body 50" used herein refers to the reference line BL of the vehicle sensor 110 and the reference reference of the vehicle body 50 when the vehicle sensor 110 rotates about the axis C. 2, the reference standard is the vehicle longitudinal direction L, the vehicle longitudinal direction L is parallel to the two-dimensional plane formed by the X axis and the Y axis, and The extending direction of the axis C of the automobile sensor 110 passes through the vehicle length direction L and is parallel to the Z axis. The reference line BL of the vehicle sensor 110 rotates about the axis C on a two-dimensional plane formed by the X axis and the Y axis, and the rotation angle of the vehicle sensor 110 is the same as the reference line BL of the vehicle sensor 110. This is an angle formed between the vehicle body 50 and the vehicle length direction L (see FIG. 2 ). The reference line BL of the vehicle sensor 110 rotates around the Z axis, and in the two-dimensional plane formed by the X axis and the Y axis, the reference line BL of the vehicle sensor 110 with respect to the vehicle longitudinal direction L of the vehicle body 50. And make an angle. Further, generally, as shown in FIG. 2, when the vehicle sensor 110 is a rider, the detection unit 112 can detect 360 degrees, and the “rotation angle of the vehicle sensor 110 with respect to the vehicle body 50” is In the description, when the detection unit 112 of the vehicle sensor 110 cannot detect 360 degrees, the vehicle sensor 110 is rotated about the axis C and the sight of the detection unit 112 is set to the detection target, or the axis C is the traveling direction. It is used to direct the aiming and mounting criteria of the. Further, the above-mentioned depiction of “X-axis”, “Y-axis”, “Z-axis” and the like will be described by way of example with reference to the drawings. There is no limit.

In this embodiment, the attitude adjustment mechanism 120 is connected to the vehicle sensor 110. The attitude adjustment mechanism 120 is used for adjusting the attitude of the vehicle sensor 110, and the attitude adjustment mechanism 120 is at least a linear adjustment mechanism, a rotation adjustment mechanism, or a combination thereof. The height of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted by the linear adjustment mechanism, for example, the vehicle sensor 110 of FIG. 2 is adjusted by moving along the Z-axis direction. Of course, the position of the automobile sensor 110 with respect to the vehicle body 50 may be adjusted by the linear adjustment mechanism. For example, the automobile sensor 110 of FIG. 2 is adjusted by moving in the left-right direction along the Y-axis direction (ie, , Linear movement such as left movement and right movement), or adjustment by moving the vehicle sensor 110 of FIG. 2 in the front-back direction along the X-axis direction (that is, linear movement such as front movement and rear movement). Further, the automobile sensor 110 of FIG. 2 may be adjusted by moving in an oblique direction on a two-dimensional plane formed by the X axis and the Y axis. The rotation adjustment mechanism adjusts the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and is adjusted by, for example, moving the vehicle sensor 110 in FIG. 2 on a two-dimensional plane formed by the Z axis and the X axis. Alternatively, the rotation adjustment mechanism adjusts the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50, and is adjusted, for example, by moving the vehicle sensor 110 of FIG. 2 in a two-dimensional plane formed by the X axis and the Y axis. .. In this embodiment, a combination of a linear adjustment mechanism and a rotation adjustment mechanism is adopted as the attitude adjustment mechanism 120, and the distance, inclination angle, or rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted. It should be noted that the description of the above-mentioned "X-axis", "Y-axis", "Z-axis" and the like will be described with reference to the drawings by way of example, but the present invention is not limited to this including other possible direction changes. Not something to do.

For example, as shown in FIGS. 3A to 3C, first, FIG. 3A is a schematic view showing a posture adjusting mechanism according to an embodiment of the present invention. The attitude adjusting mechanism 120 includes a connecting portion 122, a first connecting rod 124A, a second connecting rod 124B, a first driving portion 125A, a second driving portion 125B, a first moving portion 126A, and a second moving portion 126B. And two actuation units 128. The two actuation units 128 of the attitude adjusting mechanism 120 are respectively connected to the control unit 130, which is used to output a control signal to the actuation unit 128, and the actuation unit 128 is a member corresponding to the control signal ( For example, the first drive unit 125A and the second drive unit 125B) of this embodiment are driven to operate. In an embodiment not shown, the control unit is fitted in the actuation unit.

In the present embodiment, the bottom end of the vehicle sensor 110 is connected to the connecting portion 122, and the vehicle sensor 110 has the posture P1. One end of the first connecting rod 124A and one end of the second connecting rod 124B are connected to both sides of the connecting portion 122, respectively, and the other end of the first connecting rod 124A and the other end of the second connecting rod 124B are connected to the first moving portion 126A. The second moving parts 126B are connected to each other. The first driving unit 125A is used to transmit power to the first moving unit 126A, and drives the first moving unit 126A so as to move along the moving direction L1. The second driving unit 125B is used to transmit power to the second moving unit 126B, and drives the second moving unit 126B so as to move along the moving direction L1. The first driving unit 125A and the second driving unit 125B of the present embodiment are not connected to each other at a distance, and the first driving unit 125A and the second driving unit 125B are connected to the corresponding operating units 128, respectively. In other words, each actuation unit 128 drives the corresponding first drive unit 125A and second drive unit 125B. Incidentally, the term “moving direction L1” used herein refers to a direction parallel to the vehicle length direction L of FIG. 2 (that is, the X axis of FIG. 2).

In the above arrangement, FIG. 3B is a schematic view of an embodiment in which the height of the vehicle sensor with respect to the vehicle body is adjusted by the attitude adjusting mechanism of the present invention. In the present embodiment, when the adjustment request is to increase the height of the vehicle sensor 110 with respect to the vehicle body 50, the control unit 130 sends a corresponding control signal to the actuation unit 128 of the attitude adjusting mechanism 120 based on the adjustment request. Then, the attitude adjusting mechanism 120 raises the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. The detailed operation is interlocked so that the first driving unit 125A is driven and rotated by the operation unit 128 so that the first moving unit 126A moves along the first direction L2. The second driving unit 125B is driven and rotated by the other operating unit 128 so that the second moving unit 126B is interlocked so as to move along the second direction L3, and the movement stroke of the first moving unit 126A is the first. It is equal to the moving stroke of the second moving portion 126B, the first direction L2 is opposite to the second direction L3, and the first direction L2 and the second direction L3 are respectively parallel to the moving direction L1 of FIG. 3A. In this operation, the first moving portion 126A and the second moving portion 126B move so as to face each other, and the first connecting rod 124A and the second connecting rod 124B drive both sides of the connecting portion 122 to lift the connecting portion 122. At the same time, the automobile sensor 110 is interlocked to adjust the posture P2 of the automobile sensor 110 of FIG. 3B. As compared with the posture P1 of the vehicle sensor 110 of FIG. 3A, the reference line BL of the vehicle sensor 110 of FIG. 3B is higher than the reference line BL of the vehicle sensor 110 of FIG. 3A, in other words, the present embodiment is described above. The attitude adjustment mechanism 120 achieves the adjustment of the height distance of the vehicle sensor 110 with respect to the vehicle body 50. Further, the operation unit 128 of the present embodiment is a drive device such as a motor, and the first drive unit 125A and the second drive unit 125B are main screws, respectively. In other words, the attitude adjustment mechanism 120 of the present embodiment is linear. It is a combination of an adjusting mechanism and a rotation adjusting mechanism, the linear adjusting mechanism is a main screw, and the rotation adjusting mechanism is a combination of connecting rods. However, the present invention is not limited to this posture adjusting mechanism 120. In an embodiment not shown, a combination of a worm and a worm gear or a combination of a plurality of connecting rods may be used as a linear adjustment mechanism to adjust the height distance of the vehicle sensor 110 with respect to the vehicle body 50.

In another embodiment, FIG. 3C is a schematic view of adjusting an inclination angle of a vehicle sensor with respect to a vehicle body by a posture adjusting mechanism according to an embodiment of the present invention. When the adjustment request is to decrease the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the control unit 130 causes the actuation unit 128 of the attitude adjustment mechanism 120 to output a corresponding control signal based on the adjustment request, and the attitude adjustment is performed. The mechanism 120 lowers the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. The detailed operation is interlocked so that the first driving unit 125A is driven and rotated by the operation unit 128 so that the first moving unit 126A moves along the first direction L2. When the second driving unit 125B is driven and rotated by the other operating unit 128, the second moving unit 126B is interlocked so as to move along the second direction L3, and the moving stroke of the first moving unit 126A is the first. It is not equal to the moving stroke of the second moving portion 126B. The first direction L2 is opposite to the second direction L3, and the first direction L2 and the second direction L3 are parallel to the moving direction L1 of FIG. 3A, respectively. In this operation, the first moving portion 126A and the second moving portion 126B move so as to face each other, the moving stroke of the first moving portion 126A is not equal to the moving stroke of the second moving portion 126B, and the first moving portion 126A Since the moving stroke of the second moving portion 126B is longer than that of the second moving portion 126B, when both sides of the connecting portion 122 are interlocked by the first connecting rod 124A and the second connecting rod 124B, the first connecting rod 122 is connected to the connecting portion 122. One side of the connecting rod 124A is higher than the other side of the second connecting rod 124B that is connected to the connecting portion 122, the connecting portion 122 is inclined and the automobile sensor 110 is interlocked, and the posture P3 of the automobile sensor 110 in FIG. 3C is shown. Is further adjusted, and the vehicle sensor 110 is further tilted, so that the tilt angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted. As described above, the attitude adjusting mechanism 120 of this embodiment is a combination of the linear adjusting mechanism and the rotation adjusting mechanism, but the present invention is not limited to this attitude adjusting mechanism 120. In an embodiment not shown, a combination of a plurality of connecting rods may be used as a rotation adjusting mechanism to adjust the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50.

Referring back to FIG. 1, the control unit 130 is connected to the vehicle sensor 110, the control unit determines whether or not an adjustment request is present based on the situation of the driving environment, and the control unit 130 is based on the adjustment request. To determine the automatic sensor adjustment method. The attitude adjustment mechanism 120 adjusts the attitude of the vehicle sensor 110 based on the vehicle sensor automatic adjustment method determined by the control unit 130.

FIG. 4 is a flowchart showing a sensor automatic adjustment method for a vehicle according to an exemplary embodiment of the present invention. The vehicle sensor automatic adjustment method S100 of the present embodiment is applied to the vehicle sensor automatic adjustment system 100 shown in FIGS. 1 and 2, and the vehicle sensor automatic adjustment method S100 includes the following steps S110 to S130. First, step S110 is executed, and the vehicle sensor 110 is arranged on the vehicle body 50 (see FIG. 2). The vehicle sensor 110 has a posture P defined by one of a distance, an inclination angle, and a rotation angle of the vehicle sensor 110 with respect to the vehicle body 50. The distance of the vehicle sensor 110 with respect to the vehicle body 50 includes the height and position of the vehicle sensor 110 with respect to the vehicle body 50.

Next, step S120 is executed, and it is determined whether or not there is an adjustment request based on the situation ES of the traveling environment of the vehicle body 50. As shown in FIG. 5, FIG. 5 is a schematic view of a situation of a traveling environment encountered while the vehicle body of the present invention is traveling. The vehicle body 50 encounters various driving environment situations ES while moving on the road RL in the traveling direction DT. The traveling environment situation ES includes a single event or a combination of a plurality of events. The adjustment E5 event, the overtaking execution E6 event, and the like.

If there is an adjustment request in step S120, step S130 is executed. When step S130 is executed, the attitude of the vehicle sensor is adjusted based on the adjustment request, and after the adjustment, the process also returns to step A, and based on step S120, the control unit 130 continuously controls the vehicle body 50. It is determined whether or not there is an adjustment request based on the situation of the traveling environment. In FIG. 1 as an example, the control unit 130 determines whether or not there is an adjustment request based on the traveling environment situation ES described above. If there is an adjustment request, the control unit 130 determines the vehicle sensor automatic adjustment method based on the adjustment request and outputs a corresponding control signal, and the attitude adjustment mechanism 120 outputs the control signal from the control unit 130 to the vehicle. The posture P of the sensor 110 is adjusted. Hereinafter, the adjustment of the height, the inclination angle, the rotation angle, and the position of the vehicle sensor 100 with respect to the vehicle body 50 in the embodiment of steps S120 to S130 will be described in order.

6A to 6C are flowcharts of an embodiment for adjusting the height of the vehicle sensor in the vehicle sensor automatic adjustment method according to the present invention. First, referring to FIG. 6A and FIG. 1, step S121 is executed after step S120 of FIG. 4, and it is determined whether or not the posture P of the vehicle sensor 110 exceeds the height limit of the traveling environment. For example, when the vehicle body 50 travels in a traveling environment with a height restriction such as a tunnel or an underpass, the distance of the height limitation of the traveling environment is determined based on the actual traveling environment with a height restriction such as a tunnel or an underpass. ..

In step S121, when the control unit 130 determines that the posture P of the vehicle sensor 110 exceeds the height limit of the traveling environment, the adjustment request AC1 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50. Then, the height adjustment of the traveling environment is adapted, the control unit 130 outputs a corresponding control signal based on the adjustment request AC1, and the attitude adjustment mechanism 120 detects the vehicle sensor for the vehicle body 50 based on the control signal of the control unit 130. After adjusting the height of 110 and returning to step A of FIG. 4, based on step S120, the control unit 130 continuously determines whether there is an adjustment request based on the traveling environment of the vehicle body 50. Then, the attitude of the vehicle sensor is adjusted based on step S130. In the present embodiment, the posture adjusting mechanism 120 lowers the position of the automobile sensor 110 so as not to collide with it until reaching the maximum visual field. On the contrary, if it is determined to be negative in step S121, that is, if the control unit 130 determines that the posture P of the vehicle sensor 110 does not exceed the height limit of the traveling environment, step S122 is executed, It is determined whether the speed of the vehicle body 50 exceeds the set speed range. The set speed range is defined by the upper limit speed value and the lower limit speed value. The set speed range is based on the speed limit range of each road RL. For example, the road RL has a maximum speed limit, and a minimum speed limit is set in consideration of driving safety. The range between is the set speed range. If it is determined no in step S122, that is, if the control unit 130 determines that the speed of the vehicle body 50 does not exceed the set speed range, the speed of the vehicle body 50 is within the set speed range, that is, The speed of the vehicle body 50 is between the upper limit speed value and the lower limit speed value. When the vehicle body 50 is traveling within the set speed range, the automobile sensor automatic adjustment method S100 further includes the step of proceeding to the B1 stage, and first, it is determined whether or not the road gradient changes (see FIG. 6B). (Step S126), and subsequently, it is determined whether or not there is a front intersection or a curve in front of the vehicle body 50 (step S128 in FIG. 6B). When the control unit 130 determines that there is no change in the slope of the road and there is no forward intersection or curve ahead of the vehicle body 50, the control unit 130 adjusts the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed. 4 is performed, and adjustments such as raising, lowering, maintaining the current state, etc. are performed, and after the adjustment, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously monitors the traveling environment of the vehicle body 50. Whether or not there is an adjustment request, and the attitude of the vehicle sensor is adjusted based on step S130.

If it is determined in step S122 that the response is appropriate, that is, if the control unit 130 determines that the speed of the vehicle body 50 exceeds the set speed range, the speed of the vehicle body 50 is not within the set speed range, that is, At this time, the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range or lower than the lower limit speed value of the set speed range. Then, step S123 is executed and it is determined whether or not the speed of the vehicle body is higher than the upper limit speed value in the set speed range. The upper limit speed value is determined based on the maximum speed limit of each road RL, and when the control unit 130 determines that the speed of the vehicle body 50 exceeds the set speed range, the control unit 130 further determines the speed of the vehicle body 50. Is determined whether or not is fast. If the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value in the set speed range, it indicates that the speed of the vehicle body 50 is high. Subsequently, step S124 is executed to determine whether or not the front of the vehicle body is shielded. In the present embodiment, in the situation of the traveling environment in which the event of speed E2 of FIG. 5 is combined with the event of front shielding E3. Based on this, it is determined whether or not there is a subsequent adjustment request. However, the present invention does not limit the decision order of FIG. 6A. By the way, in general, when the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range, it indicates that the vehicle body 50 speed is high, and the adjustment request is for the vehicle body 50. The height of the sensor 110 is increased, the control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjustment mechanism 120 determines the height of the vehicle sensor 110 relative to the vehicle body 50 based on the control signal of the control unit 130. That is, the detection range of the automobile sensor 110 is set to a distant place. Further, after performing the step of increasing the height of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to the step A of FIG. 4, and the control unit 130 continuously monitors the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, when the control unit 130 determines that the speed of the vehicle body 50 is not higher than the upper limit speed value of the set speed range, the control unit 130 determines whether the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range. Is further judged. When the control unit 130 determines that the speed of the vehicle body 50 is lower than the lower limit speed value in the set speed range, it indicates that the vehicle body 50 is slow. In this case, attention must be paid to the driving environment in the vicinity, the adjustment request is to lower the height of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 causes the corresponding control signal to be output based on the adjustment request. The attitude adjusting mechanism 120 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, and brings the detection range of the vehicle sensor 110 closer. In addition, after performing the step of lowering the height of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously monitors the traveling environment of the vehicle body 50. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

Returning to FIG. 6A, when it is determined in step S124 that the front of the vehicle body 50 is blocked by the control unit 130, the speed of the vehicle body 50 is found to be high based on the determination in step S123, and the adjustment request AC1 is The height of the vehicle sensor 110 with respect to the vehicle body 50 is lowered, the control unit 130 outputs a corresponding control signal based on the adjustment request AC1, and the attitude adjustment mechanism 120 receives the vehicle body 50 based on the control signal from the control unit 130. After lowering the height of the automobile sensor 110 and adjusting, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously makes an adjustment request based on the situation of the traveling environment of the vehicle body 50. Is determined and the attitude of the vehicle sensor is adjusted based on step S130. As described above, when the speed of the vehicle body 50 is high when the front view of the vehicle body 50 is blocked, the detection range to be watched by the vehicle sensor 110 is near, and the height of the vehicle sensor 110 with respect to the vehicle body 50 is set to be close. Lower and adapt to obstacles. However, the present invention is not limited to this, and in an embodiment (not shown), when the control unit 130 determines that the front of the vehicle body 50 is shielded, the distance adjustment of the detection range of the vehicle sensor 110 is adjusted. Then, by adjusting the height of the vehicle sensor 110 with respect to the vehicle body 50, it is selected whether to respond to the obstacle or to exceed the obstacle. However, after the height of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted to select whether to respond to or exceed the obstacle, the process returns to step A of FIG. Based on the above, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and adjusts the attitude of the vehicle sensor based on step S130.

In the present embodiment, if it is determined in step S124 that the front of the vehicle body 50 is not shielded by the control unit 130, then step S125 is executed to determine whether or not there is a change in the terrain in front of the vehicle body 50. Is judged. By the way, the term "terrain change" as used herein refers to whether there is a change in the slope of the road or whether there is a forward crossing or a curve in front of the vehicle body. In the present embodiment, when the control unit 130 determines that there is no change in the terrain in front of the vehicle body, the adjustment request AC3 adjusts the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed, and performs the adjustment. Then, returning to step A of FIG. 4, the control unit 130 continuously determines whether or not there is an adjustment request based on the situation of the traveling environment of the vehicle body 50 based on step S120, and then proceeds to step S130. Based on this, the attitude of the vehicle sensor is adjusted. In other words, at this time, the control unit 130 causes the corresponding control signal to be output based on the adjustment request AC3, and when the speed of the vehicle body 50 is high, the posture adjustment mechanism 120 outputs the control signal to the vehicle body 50 based on the control signal of the control unit 130. Raise the height of the automotive sensor 110. On the contrary, when the speed of the vehicle body 50 is slow, the posture adjusting mechanism 120 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, and after the adjustment, also proceeds to step A of FIG. Returning to step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and based on step S130, the attitude adjustment of the vehicle sensor is performed. I do.

In the present embodiment, in step S125, when the control unit 130 determines that there is a change in the terrain in front of the vehicle body, the attitude of the vehicle sensor 110 is adjusted based on the event of the change in the terrain. Specifically, step S125 of determining that there is a change in the terrain in front of the vehicle body 50 includes step B1. Subsequently, referring to FIG. 6B, step S126 is executed, and it is determined whether or not the road gradient has changed. When the control unit 130 determines that the road gradient has changed, step S127 is subsequently executed to determine whether the road gradient is uphill or downhill. When the control unit 130 determines that the slope of the road is uphill, the adjustment request AC1 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 performs corresponding control based on the adjustment request AC1. A signal is output, and the attitude adjusting mechanism 120 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, and after adjustment, returns to step A of FIG. 4 and proceeds to step S120. Based on this, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and adjusts the attitude of the vehicle sensor based on step S130. When the vehicle body 50 travels uphill, the attitude adjusting mechanism 120 aims at the detection range of the vehicle sensor 110 to the near side, thereby avoiding the situation where all the laser light of the vehicle sensor 110 is directed to the air or a distance. Let On the contrary, when the control unit 130 determines that the slope of the road is downhill, the adjustment request AC2 is to decrease the height of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 determines based on the adjustment request AC2. A corresponding control signal is output, the attitude adjustment mechanism 120 raises the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, and after adjustment, returns to step A of FIG. Based on step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and based on step S130, adjusts the attitude of the vehicle sensor. When the vehicle body 50 travels on a downhill, the attitude adjustment mechanism 120 sets the detection range of the vehicle sensor 110 to a distant position. For example, when the downhill is connected to a flat road, when the vehicle body 50 travels on the downhill, by raising the height of the vehicle sensor 110 with respect to the vehicle body 50, it is possible to confirm a distant target on the flat road. To

In the present embodiment, if it is determined in step S126 that the slope of the road has not changed, then step S128 is executed to determine whether or not there is a front intersection or a curve ahead of the vehicle body 50. Is judged. When it is determined by the control unit 130 that there is no front intersection or curve in front of the vehicle body 50, that is, when there is no intersection in front of the vehicle body 50, the process proceeds to step D1 and the adjustment request AC3 shown in FIG. The height of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted based on the speed, and after the adjustment, the process returns to step A of FIG. 4 and the control unit 130 continuously controls the vehicle body 50 based on step S120. Whether or not there is an adjustment request is determined based on the state of the traveling environment, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, if the control unit 130 determines that there is a front intersection or a curve in front of the vehicle body 50, that is, if there is an intersection in front of the vehicle body 50, the adjustment request AC2 indicates that the vehicle sensor 110 for the vehicle body 50 is to be adjusted. When the height is increased, the control unit 130 outputs a corresponding control signal based on the adjustment request AC2, and the attitude adjustment mechanism 120 determines the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal from the control unit 130. After raising and adjusting, the process also returns to step A of FIG. 4, and based on step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the state of the traveling environment of the vehicle body 50. Then, the attitude of the vehicle sensor is adjusted based on step S130. When there is a front intersection or a curve in front of the vehicle body 50, the attitude adjustment mechanism 120 sets the detection range of the vehicle sensor 110 to a distant position. In this way, the road conditions in the front (for example, the intersection or the curve in the front) are confirmed, and the selection judgment is provided when the vehicle body 50 is traveling.

In the present embodiment, the above steps S124 to S128 return to FIG. 6A based on the determination that the speed of the vehicle body 50 is high in step S123, and first, in step S122, the speed of the vehicle body 50 exceeds the set speed range. Make sure that That is, the speed of the vehicle body 50 at this time is higher than the upper limit speed value of the set speed range or lower than the lower limit speed value of the set speed range. Subsequently, in step S123, when the control unit 130 determines that the speed of the vehicle body 50 is not higher than the upper limit speed value of the set speed range, the control unit 130 determines that the speed of the vehicle body 50 is the lower limit speed value of the set speed range. It is further determined whether it is lower. When the control unit 130 determines that the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range, the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range, and the speed of the vehicle body 50 is slow. Shown, stage C1 is performed. Subsequently, referring to FIG. 6C, step S224 is executed to determine whether or not the front of the vehicle body is shielded. When the control unit 130 determines that the front of the vehicle body 50 is shielded, it is confirmed by the determinations in steps S122 and S123 that the vehicle body 50 is slow, and the adjustment request AC2 is for the vehicle body 50 with respect to the vehicle body. Assuming that the height of the sensor 110 is increased, the control unit 130 outputs a corresponding control signal based on the adjustment request AC2, and the posture adjustment mechanism 120 detects the vehicle sensor 50 for the vehicle body 50 based on the control signal from the control unit 130. After the height is raised and the adjustment is performed, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the state of the traveling environment of the vehicle body 50. Then, the attitude of the vehicle sensor is adjusted based on step S130. In this way, when the front view of the vehicle body 50 is blocked, the speed of the vehicle body 50 is low, and the detection range to be watched by the vehicle sensor 110 is far, and the detection range of the vehicle sensor 110 is an obstacle. If there is another obstacle in front of the obstacle, or whether the road condition in front of the obstacle (for example, an intersection or a curve in front) is checked, a decision for selection is made when the vehicle body 50 is running. I will provide a. However, the present invention is not limited to this, and in the embodiment not shown, when the control unit 130 determines that the front of the vehicle body 50 is shielded, the perspective of the detection range of the vehicle sensor 110 is adjusted. The height of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted to select whether to respond to the obstacle or to exceed the obstacle. However, after the height of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted to select whether to respond to or exceed the obstacle, the process returns to step A of FIG. Based on the above, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and adjusts the attitude of the vehicle sensor based on step S130.

In the present embodiment, if it is determined in step S224 that the front of the vehicle body 50 is not shielded by the control unit 130, then step S225 is executed to determine whether or not there is a change in the terrain in front of the vehicle body 50. Is judged. When the control unit 130 determines that there is no change in the terrain in front of the vehicle body, the adjustment request AC3 adjusts the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed, and after the adjustment, the adjustment of FIG. Returning to stage A, the control unit 130 continuously determines whether there is an adjustment request based on the state of the traveling environment of the vehicle body 50 based on step S120, and the vehicle sensor based on step S130. Adjust the posture of. If the control unit 130 determines in step S225 that there is a change in the terrain in front of the vehicle body, then step S226 is executed to determine whether or not the slope of the road has changed. When the control unit 130 determines that there is a change in the slope of the road, step S227 is subsequently executed to determine whether the slope of the road is an uphill slope or a downhill slope. When the control unit 130 determines that the slope of the road is uphill, the adjustment request AC1 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 performs corresponding control based on the adjustment request AC1. A signal is output, and the attitude adjusting mechanism 120 lowers the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. This avoids the situation where all the laser light of the automobile sensor 110 is directed to the air or a distance. In addition, after performing the step of lowering the height of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously monitors the traveling environment of the vehicle body 50. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, when the control unit 130 determines that the slope of the road is downhill, the adjustment request AC2 is to increase the height of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 is based on the adjustment request AC2. A corresponding control signal is output, and the attitude adjustment mechanism 120 raises the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. In this way, it is possible to see a distant target on a flat road after a downhill. Further, after performing the step of increasing the height of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to the step A of FIG. 4, and the control unit 130 continuously monitors the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

In this embodiment, if the control unit 130 determines in step S226 that there is no change in the road gradient, then step S228 is executed to determine whether or not there is a front intersection or a curve in front of the vehicle body. To be judged. When the control unit 130 determines that there is no front intersection or a curve in front of the vehicle body 50, that is, when there is no intersection in front of the vehicle body 50, the adjustment request AC3 indicates that the vehicle sensor 110 for the vehicle body 50 is based on the speed. The height of the vehicle is adjusted, and after the adjustment, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously requests the adjustment based on the situation of the traveling environment of the vehicle body 50. Is determined and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, if the control unit 130 determines that there is a front intersection or a curve in front of the vehicle body 50, that is, if there is an intersection in front of the vehicle body 50, the adjustment request AC2 indicates that the vehicle sensor 110 for the vehicle body 50 is to be adjusted. When the height is increased, the control unit 130 outputs a corresponding control signal based on the adjustment request AC2, and the attitude adjustment mechanism 120 determines the height of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal from the control unit 130. Raise and check the road conditions in front (for example, intersections and curves in front) and provide a selection decision when the vehicle body 50 is running. Further, after performing the step of increasing the height of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to the step A of FIG. 4, and the control unit 130 continuously monitors the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

7A to 7C are flowcharts for adjusting the inclination angle of the vehicle sensor in the vehicle sensor automatic adjustment method according to the embodiment of the present invention. Incidentally, the automobile sensor automatic adjustment method of FIGS. 7A to 7C is similar to the automobile sensor automatic adjustment method of FIGS. 6A to 6C, and the same steps are denoted by the same reference numerals and have the same effect, and thus duplicate description will be omitted. Avoid them, and only the differences will be explained below. First, referring to FIG. 7A and FIG. 1, step S123 is executed to determine whether the speed of the vehicle body is higher than the upper limit speed value of the set speed range, and the upper limit speed value is set to the maximum speed limit of each road RL. It is decided based on. When the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range, it indicates that the speed of the vehicle body 50 is high. In other words, the control unit 130 causes the speed of the vehicle body 50 to be higher than the set speed. When it is determined that the vehicle body 50 is out of the range, it is further determined by the control unit 130 whether or not the speed of the vehicle body 50 is high. Subsequently, step S124 is executed to determine whether or not the front of the vehicle body is shielded. In other words, in the present embodiment, it is determined whether the event of the front shielding E3 is combined with the event of the speed E2 of FIG. 5 and there is a subsequent adjustment request. The present invention does not limit the determination order of FIG. 7A. Incidentally, in general, when the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range, it indicates that the vehicle body 50 speed is high, and the adjustment request is for the vehicle body 50. When the inclination angle of the sensor 110 is increased, the control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjusting mechanism 120 tilts the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. The angle is raised to make the detection range of the automobile sensor 110 far. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, when the control unit 130 determines that the speed of the vehicle body 50 is not higher than the upper limit speed value of the set speed range, the control unit 130 determines whether the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range. Is further judged. When the control unit 130 determines that the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range, it indicates that the vehicle body 50 is slow, and attention should be paid to the driving environment in the vicinity or the target object in the vicinity. The adjustment request is to lower the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50. The control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjusting mechanism 120 lowers the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130 to detect the vehicle sensor 110. Move the range closer. In addition, after performing the step of lowering the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. In addition, in step S122, when the control unit 130 determines that the speed of the vehicle body 50 is within the set speed range, the vehicle body 50 is traveling within the set speed range. The automobile sensor automatic adjustment method S100 further includes a step of proceeding to the B2 stage, and it is first determined whether or not there is a change in the slope of the road (step S126 in FIG. 7B), and then in front of the vehicle body 50 to be judged. Alternatively, it is determined whether or not there is a curve (step S128 in FIG. 7B), and it is determined by the control unit 130 that there is no change in the slope of the road and that there is no forward intersection or curve in front of the vehicle body 50. In this case, the control unit 130 adjusts the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed and raises, lowers, or maintains the current state. After the adjustment, the process returns to step A of FIG. 4, and based on step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50. ..

Returning to FIG. 7A, when it is determined in step S124 that the front of the vehicle body 50 is shielded by the control unit 130, it is determined from the determination in step S123 that the vehicle body 50 has a high speed, and the adjustment request AC4 indicates that the vehicle body 50 is fast. With respect to the vehicle sensor 110, the tilt angle of the vehicle sensor 110 is lowered, the control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjusting mechanism 120 outputs the control signal from the control unit 130 to the vehicle sensor with respect to the vehicle body 50. After lowering the inclination angle of 110 and returning to the stage A of FIG. 4 after the adjustment, the control unit 130 continuously makes an adjustment request based on the situation of the traveling environment of the vehicle body 50 based on step S120. Then, the attitude of the vehicle sensor is adjusted based on step S130. As described above, when the speed of the vehicle body 50 is high when the front field of view of the vehicle body 50 is blocked, the detection range to be watched by the vehicle sensor 110 becomes close, and the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 is changed. Lower to accommodate obstacles. However, the present invention is not limited to this, and in an embodiment (not shown), when the control unit 130 determines that the front of the vehicle body 50 is shielded, the perspective adjustment of the detection range of the vehicle sensor 110 is performed. Then, by adjusting the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, it is selected whether to respond to the obstacle or to move beyond the obstacle. However, after the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted to select whether to correspond to the obstacle or to exceed the obstacle, the process returns to step A of FIG. 4 and proceeds to step S120. Based on this, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and adjusts the attitude of the vehicle sensor based on step S130.

In the present embodiment, if it is determined in step S124 that the front of the vehicle body 50 is not shielded by the control unit 130, then step S125 is executed to determine whether or not there is a change in the terrain in front of the vehicle body 50. Is judged. When the control unit 130 determines that there is no change in the terrain in front of the vehicle body, the adjustment request AC6 adjusts the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed. In other words, at this time, the control unit 130 causes the corresponding control signal to be output based on the adjustment request, and after the adjustment, returns to the step A of FIG. 4 to continue the control unit 130 based on the step S120. To determine whether or not there is an adjustment request based on the traveling environment of the vehicle body 50. When the speed of the vehicle body 50 is high, the attitude adjusting mechanism 120 increases the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. On the contrary, when the speed of the vehicle body 50 is slow, the attitude adjusting mechanism 120 lowers the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, and after the adjustment, also proceeds to step A of FIG. Returning to step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50, and based on step S130, the attitude adjustment of the vehicle sensor is performed. I do.

In the present embodiment, when the control unit 130 determines that there is a change in the terrain in front of the vehicle body in step S125, step B2 is subsequently executed, step S126 is executed with reference to FIG. It is determined whether or not there is a change in the gradient of. When the control unit 130 determines that there is a change in the road gradient, then step S127 is executed to determine whether the road gradient is an uphill or a downhill. When the control unit 130 determines that the slope of the road is uphill, the adjustment request AC4 is to decrease the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 performs the corresponding control based on the adjustment request AC4. A signal is output, and the attitude adjusting mechanism 120 lowers the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, thereby avoiding a situation in which all the laser light of the vehicle sensor 110 is directed to the air or a distance. Let In addition, after performing the step of lowering the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, when the control unit 130 determines that the slope of the road is downhill, the adjustment request AC5 is to increase the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 is based on the adjustment request AC5. A corresponding control signal is output, and the attitude adjusting mechanism 120 raises the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, so that a distant target on a flat road after a downhill can be confirmed. To do. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

In the present embodiment, if it is determined in step S126 that the slope of the road has not changed, then step S128 is executed to determine whether or not there is a front intersection or a curve in front of the vehicle body. To be judged. When it is determined by the control unit 130 that there is no front intersection or curve in front of the vehicle body 50, that is, when there is no intersection in front of the vehicle body 50, the process proceeds to step D2 and the adjustment request AC6 shown in FIG. The tilt angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted based on the speed, and after the adjustment, the process returns to step A of FIG. 4 and the control unit 130 continuously controls the vehicle body 50 based on step S120. Whether or not there is an adjustment request is determined based on the state of the traveling environment, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, in step S128, when the control unit 130 determines that there is a front intersection or a curve ahead of the vehicle body 50, the adjustment request AC5 is to increase the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 130 causes the corresponding control signal to be output based on the adjustment request AC5, and the attitude adjustment mechanism 120 raises the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130 to detect the detection range of the vehicle sensor 110. Aim at a distance. Thereby, the road condition in the front (for example, the intersection or the curve in the front) is confirmed, and the judgment of the selection is provided when the vehicle body 50 is traveling. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

In the present embodiment, the above steps S124 to S128 return to FIG. 7A based on the determination that the speed of the vehicle body 50 is high in step S123, and first, in step S122, the speed of the vehicle body 50 exceeds the set speed range. Is confirmed. That is, the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range or lower than the lower limit speed value of the set speed range. Subsequently, in step S123, when the control unit 130 determines that the speed of the vehicle body 50 is not higher than the upper limit speed value of the set speed range, the control unit 130 determines that the speed of the vehicle body 50 is the lower limit speed value of the set speed range. It is further determined whether it is lower. When the control unit 130 determines that the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range, it indicates that the speed of the vehicle body 50 is lower than the lower limit speed value of the set speed range and the vehicle body 50 is slow. , C2 stage is executed. Referring to FIG. 7C, subsequently, step S224 is executed to determine whether or not the front of the vehicle body is shielded. When the control unit 130 determines that the front of the vehicle body 50 is shielded, the speed of the vehicle body 50 is slow based on the determinations in steps S122 and S123 described above, and the adjustment request AC5 indicates that the vehicle sensor 110 for the vehicle body 50. The control unit 130 outputs a corresponding control signal based on the adjustment request AC5, and the attitude adjustment mechanism 120 determines the tilt angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal from the control unit 130. To check whether there is another obstacle in front of the obstacle or to check the road condition in front (for example, a crossroad or a curve in front). And provide a selection decision when the vehicle body 50 is running. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

In the present embodiment, if it is determined in step S224 that the front of the vehicle body 50 is not shielded by the control unit 130, then step S225 is executed to determine whether or not there is a change in the terrain in front of the vehicle body 50. Is judged. When the control unit 130 determines that there is no change in the terrain in front of the vehicle body, the adjustment request AC6 adjusts the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed, and after the adjustment, the adjustment of FIG. Returning to stage A, the control unit 130 continuously determines whether there is an adjustment request based on the state of the traveling environment of the vehicle body 50 based on step S120, and the vehicle sensor based on step S130. Adjust the posture of. When it is determined by the control unit 130 that there is a change in the terrain in front of the vehicle body in step S225, step S226 is subsequently executed to determine whether or not there is a change in the slope of the road. When the control unit 130 determines that there is a change in the slope of the road, step S227 is subsequently executed to determine whether the slope of the road is an uphill slope or a downhill slope. When the control unit 130 determines that the slope of the road is uphill, the adjustment request AC4 is to decrease the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 performs the corresponding control based on the adjustment request AC4. A signal is output, and the attitude adjusting mechanism 120 lowers the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. In this way, the laser light of the vehicle sensor 110 is directed toward the air or a distance. Avoid it. In addition, after performing the step of lowering the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. On the contrary, when the control unit 130 determines that the slope of the road is downhill, the adjustment request AC5 is to increase the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 is based on the adjustment request AC5. A corresponding control signal is output, and the attitude adjusting mechanism 120 raises the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130, so that a distant target on a flat road after a downhill can be confirmed. To do. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

In the present embodiment, if it is determined in step S226 that the slope of the road has not changed, then step S228 is executed to determine whether there is a front intersection or a curve in front of the vehicle body. Is determined. When the control unit 130 determines that there is no front intersection or curve in front of the vehicle body 50, the adjustment request AC6 adjusts the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the speed, and after the adjustment, Returning to stage A of FIG. 4, based on step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the situation of the traveling environment of the vehicle body 50, and based on step S130. Adjust the attitude of the car sensor. On the contrary, when the control unit 130 determines that there is a front intersection or a curve in front of the vehicle body 50, the adjustment request AC5 is to increase the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, and the control unit 130 requests the adjustment. A corresponding control signal is output based on AC5, and the attitude adjusting mechanism 120 raises the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. In addition, after performing the step of increasing the inclination angle of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and the control unit 130 continuously determines the traveling environment of the vehicle body 50 based on step S120. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130.

FIG. 8 is a flowchart for adjusting the rotation angle of the vehicle sensor in the vehicle sensor automatic adjustment method according to the embodiment of the present invention. FIG. 9A is a schematic diagram when the state of the traveling environment of the vehicle body according to the embodiment of the present invention is an event of lateral adjustment. 9B is a schematic diagram of adjusting the rotation angle of the vehicle sensor with respect to the vehicle body of FIG. 9A according to one embodiment. 8 and 9A are illustrations of the event of lateral adjustment E5 of FIG. 5 according to one embodiment. Incidentally, in general, when the vehicle sensor 110 is a rider (see FIG. 2), the detection unit 112 can detect 360 degrees, and in this embodiment, the detection unit 112 of the vehicle sensor 110 detects 360 degrees. When it is not possible, the automobile sensor 110 is rotated about the axis C and the aim of the detection unit 112 is aligned with the object to be detected, or the axis C is used to aim in the traveling direction and to set a reference for mounting. .. Referring to FIG. 8, step S321 is executed after step S120 in FIG. 4, and it is determined whether or not one front side of the vehicle body 50 is shielded. As shown in FIG. 9A, while the vehicle body 50 is traveling, the vehicle sensor 110 has the detection distance DR, and the first side surface S1 and the second side surface S2 are on the left and right sides of the detection center CL, respectively. Incidentally, the term “one side is shielded” used here means that the detection center CL of the detection distance DR of the automobile sensor 110 is not shielded and only one side of the detection center CL of the detection distance DR is shielded. .. On the contrary, when the obstacle is located at least at the detection center CL of the detection distance DR of the vehicle sensor 110, the front of the vehicle body is shielded. Taking FIG. 9A as an example, the obstacle 40 is located on the front left side of the vehicle body 50, the first side surface S1 of the detection distance DR of the vehicle sensor 110 is shielded, and the front side of the vehicle body 50 is shielded on one side, This side is called the shield side, that is, the first side surface S1 of FIG. 9A.

In this embodiment, when the control unit 130 determines in step S321 that one side of the front of the vehicle body 50 is not shielded, the vehicle body 50 does not have an adjustment request, and the process returns to the stage A, that is, FIG. In step S120, the control unit 130 continuously determines whether or not there is an adjustment request based on the state of the traveling environment of the vehicle body 50. On the contrary, if the control unit 130 determines that one side of the front of the vehicle body 50 is shielded, then step S323 is executed to determine whether or not the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range. It is determined whether or not the upper limit speed value in the set speed range is determined based on the maximum speed limit of each road RL. In other words, the control unit 130 determines whether or not the speed of the vehicle body 50 is high. When the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range, it indicates that the speed of the vehicle body 50 is high, and the adjustment request AC7 indicates the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50. Adjustments will be made so that they are moved in the direction of the shield side. The control unit 130 outputs a corresponding control signal based on the adjustment request AC7, and the attitude adjustment mechanism 120 moves the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 in the shielding direction based on the control signal of the control unit 130. The adjustment is performed, and after the adjustment, the process returns to step A in FIG. 4 and, based on step S120, whether the control unit 130 continuously makes an adjustment request based on the traveling environment of the vehicle body 50. It is determined whether or not the attitude of the vehicle sensor is adjusted based on step S130. 9B as an example, when the speed of the vehicle body 50 is high when one side of the front field of view of the vehicle body 50 is blocked, the detection range to be watched by the vehicle sensor 110 is near, and the vehicle sensor for the vehicle body 50 is close. It is selected that the rotation angle of 110 is adjusted so as to move in the direction of the first side surface S1 so as to correspond to the obstacle 40.

In the present embodiment, in step S323, if the speed of the vehicle body 50 is not higher than the upper limit speed value in the set speed range, step S325 is executed to determine whether the speed of the vehicle body 50 is lower than the lower limit speed value in the set speed range. It is determined whether or not the lower limit speed value in the set speed range is the minimum speed limit based on the travel speed limit range of each road RL. If it is determined to be no in step S325, it indicates that the speed of the vehicle body 50 is not lower than the lower limit speed value of the set speed range, and the speed of the vehicle body 50 is also set to the upper limit speed of the set speed range by the control unit 130 in step S323. When it is determined that the speed is not higher than the value, it indicates that the speed of the vehicle body 50 is within the set speed range. In other words, whether there is no adjustment request for the vehicle body 50, the process returns to the step A, and in step S120 of FIG. 4, the control unit 130 continuously makes an adjustment request based on the traveling environment of the vehicle body 50. Let me judge whether or not. On the contrary, if it is determined in step S325 that the vehicle body 50 has a speed lower than the lower limit speed value of the set speed range and the vehicle body 50 has a slow speed, the adjustment request AC8 indicates that the vehicle sensor The rotation angle will be adjusted so that it moves in the opposite direction to the shielding side. The control unit 130 outputs a corresponding control signal based on the adjustment request AC8, and the attitude adjustment mechanism 120 moves the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 in the opposite direction of the shielding side based on the control signal of the control unit 130. Adjustment is performed, and after the adjustment, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously makes an adjustment request based on the state of the traveling environment of the vehicle body 50. Then, the attitude of the vehicle sensor is adjusted based on step S130. When the speed of the vehicle body 50 is slow when one side of the front field of view of the vehicle body 50 is blocked, the detection range to be watched by the vehicle sensor 110 is far, or there is no need to deal with obstacles at present. The rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted so as to move in the direction of the second side surface S2 so that it does not correspond to the obstacle 40.

In FIGS. 8 and 9B described above, by adjusting the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50, the situation ES of the traveling environment of the vehicle body of FIG. 9A is set as the adjustment request for the lateral adjustment E5. However, the present invention is not limited to this, and by adjusting the position of the vehicle sensor 110 with respect to the vehicle body 50, the situation ES of the traveling environment of the vehicle body 50 may be used as the adjustment request of the lateral adjustment E5, and the determination at this step is Similar to FIG. The same steps are denoted by the same reference numerals, and since they have the same effect, duplicate description will be omitted, and only the differences will be described below. Referring to FIG. 9C, this is a schematic diagram for adjusting the position of the vehicle sensor with respect to the vehicle body of FIG. 9A according to one embodiment. In step S323 of FIG. 8, it is determined whether the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range. If the control unit 130 determines that the speed of the vehicle body 50 is higher than the upper limit speed value of the set speed range, it indicates that the vehicle body speed is fast, and the adjustment request indicates that the position of the vehicle sensor 110 with respect to the vehicle body 50 is on the shield side. Adjustments will be made to move in the direction of. The control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjusting mechanism 120 moves the position of the vehicle sensor 110 with respect to the vehicle body 50 in the shielding direction based on the control signal of the control unit 130. After the adjustment, and after the adjustment, the procedure returns to step A of FIG. 4 and, based on step S120, whether the control unit 130 continuously requests the adjustment based on the situation of the traveling environment of the vehicle body 50. And the attitude of the vehicle sensor is adjusted based on step S130. As a result, when one side of the front field of view of the vehicle body 50 is shielded and the speed of the vehicle body 50 is high, the detection range to be watched by the vehicle sensor 110 is near, and the position of the vehicle sensor 110 with respect to the vehicle body 50 is close. Is adjusted so as to move in the direction of the first side surface S1 (in the example of FIG. 9A, the automobile sensor 110 moves to the left), and it is selected to correspond to the obstacle 40.

On the contrary, when it is determined to be appropriate in step S325, the speed of the vehicle body 50 is lower than the lower limit speed value in the set speed range, indicating that the vehicle body 50 is slow, and the adjustment request is issued by the vehicle sensor 110 to the vehicle body 50. Adjustment shall be made so that the position moves in the opposite direction to the shield side. The control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjustment mechanism 120 moves the position of the vehicle sensor 110 with respect to the vehicle body 50 in the opposite direction of the shielding side based on the control signal of the control unit 130. After the adjustment, the process returns to step A of FIG. 4 and, based on step S120, whether the control unit 130 continuously requests the adjustment based on the traveling environment of the vehicle body 50 or not. Then, the attitude of the vehicle sensor is adjusted based on step S130. When the speed of the vehicle body 50 is slow when one side of the front field of view of the vehicle body 50 is shielded, the detection range to be watched by the vehicle sensor 110 is distant, or there is no need to deal with obstacles at present. , The position of the automobile sensor 110 with respect to the vehicle body 50 is adjusted so as to move in the direction of the second side surface S2 (in the example of FIG. 9C, the automobile sensor 110 moves to the right), and does not correspond to the obstacle 40. In this way, the vehicle sensor 110 focuses on the information in front of the obstacle 40. By the way, the coverage of the detection distance DR in FIG. 9C is merely an outline, and the present invention is not limited thereto.

In an embodiment not shown, the event of the adjustment E5 in the horizontal direction of FIG. 5 may be combined with the event of the overtaking execution E6 to determine whether or not there is a subsequent adjustment request. Referring to FIGS. 1, 8 and 9A, first, it is determined whether or not overtaking is being executed. When the control unit 130 determines that the overtaking is being executed, the adjustment request is to make an adjustment so that the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 is moved in the overtaking direction. The control unit 130 outputs a corresponding control signal based on the adjustment request, and the attitude adjusting mechanism 120 moves in the direction of the side overtaking the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 based on the control signal of the control unit 130. The adjustment is performed, and after the adjustment, the process returns to step A in FIG. 4 and, based on step S120, whether the control unit 130 continuously makes an adjustment request based on the traveling environment of the vehicle body 50. It is determined whether or not the attitude of the vehicle sensor is adjusted based on step S130. In the example of FIG. 9B, the vehicle body 50 is overtaken from the right side of the obstacle 40, and the rotation angle of the vehicle sensor 110 with respect to the vehicle body 50 is adjusted to move to the left side so that the obstacle 40 can be dealt with. Selected. When the control unit 130 determines that the overtaking is not performed, the adjustment request is to adjust the posture P of the vehicle sensor 110 based on the event of the lateral adjustment. For example, the determination in FIG. The posture P of the vehicle sensor 110 is adjusted based on the flowchart, and after the adjustment, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously determines the running environment of the vehicle body 50. It is determined whether or not there is an adjustment request based on the situation, and the attitude of the vehicle sensor is adjusted based on step S130. The present invention is not limited to this, and the adjustment request for the overtaking execution E6 may be made by adjusting the position of the vehicle sensor 110 with respect to the vehicle body 50 and adjusting the position ES of the vehicle body 50. For example, the vehicle body 50 may be overtaken from the right side of the obstacle 40, the position of the vehicle sensor 110 with respect to the vehicle body 50 may be adjusted to move to the left side, and the vehicle body 50 may be selected to correspond to the obstacle 40. In addition, after performing the step of adjusting the position of the vehicle sensor 110 with respect to the vehicle body 50, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously monitors the traveling environment of the vehicle body 50. It is determined whether or not there is an adjustment request based on, and the attitude of the vehicle sensor is adjusted based on step S130. When the control unit 130 determines that the overtaking is not performed, the adjustment request is to adjust the posture P of the vehicle sensor 110 based on the event of the lateral adjustment. For example, the determination in FIG. The posture P of the vehicle sensor 110 is adjusted based on the flowchart, and after the adjustment, the process returns to step A of FIG. 4 and, based on step S120, the control unit 130 continuously determines the running environment of the vehicle body 50. It is determined whether or not there is an adjustment request based on the situation, and the attitude of the vehicle sensor is adjusted based on step S130.

FIG. 10 is a schematic diagram showing a sensor automatic adjustment system for a vehicle according to another embodiment of the present invention. Incidentally, the automobile sensor automatic adjustment system 200 in FIG. 10 is similar to the automobile sensor automatic adjustment system 100 in FIG. Only the differences will be described below. The automotive sensor automatic adjustment system 200 of FIG. 10 further includes an image information module 140. The image information module 140 is connected to the control unit 130, and the image information module 140 is used to provide image information to the control unit 130. The image information provided by the image information module 140 includes a point cloud map formed by accumulating a plurality of point clouds, and the point cloud has at least geometric position (three-dimensional coordinate) information. Other than the above, it also has color information and intensity information of the reflecting surface of the target object, and obtains the status information of the driving environment including the height of the driving environment, road gradient, obstacles, intersections, etc. from the point cloud map of the image information. It is possible. Further, the control unit 130 acquires the speed of the vehicle body 50 based on the signal comparison between the image information module 140 and the vehicle sensor 110. For example, the control unit 130 determines the current position of the vehicle body 50 in the point cloud map based on the comparison between the point cloud detected by the vehicle sensor 110 of the rider and the point cloud of the point cloud map of the image information module 140. The speed of the vehicle body 50 is calculated by using the position information obtained at different times.

Referring to step S120 of FIG. 4, in the present embodiment, the image information module 140 is further combined to predict the traveling environment situation of the vehicle body 50 based on the image information, and the traveling environment situation of the image information is transmitted to the control unit 130. Provided. The control unit 130 determines whether or not there is an adjustment request by combining the image information, and adjusts the attitude of the vehicle sensor 110. The control unit 130 is implemented by hardware (eg, processor, host computer), software (eg, program instructions executed by processor), or a combination thereof. As described above, the control unit 130 of the present embodiment combines the height information of the traveling environment obtained from the image information of the image information module 140, the road gradient, the obstacle, the situation information of the traveling environment such as the intersection, and the adjustment request. Based on the above, it is determined how to adjust the vehicle sensor 110, a corresponding control signal is output, and the attitude adjustment mechanism 120 adjusts the attitude of the vehicle sensor 110 based on the control signal of the control unit 130. After the adjustment, the process returns to step A of FIG. 4 and the control unit 130 continuously determines whether or not there is an adjustment request based on the traveling environment of the vehicle body 50 based on step S120. The attitude of the vehicle sensor is adjusted based on step S130. Further, as shown in FIG. 5, the traveling environment situation ES includes a single event or a combination of a plurality of events, for example, a traveling environment height E1 event, a speed E2 event, a front shielding E3 event, Topographic change E4 event, lateral adjustment E5 event, and overtaking execution E6 event are included. The control unit 130 includes an algorithm, such as a height E1 event of the driving environment, a speed E2 event, a front obstruction E3 event, a terrain change E4 event, a lateral adjustment E5 event, and an overtaking execution E6 event. When a plurality of events are combined, the control unit 130 prioritizes the adjustment requests for these events by an algorithm policy. For example, in the automobile sensor automatic adjustment method of FIGS. 6A to 7C, the adjustment request order is the event of the height E1 of the traveling environment, the event of the front shielding E3, the event of the speed E2, and the event of the terrain change E4. There is.

Further, after step S130 of the attitude of the adjusted vehicle sensor 110, the relative relationship between the adjusted vehicle sensor 110 and the vehicle body 50 is corrected, and, for example, the operation unit 128 of the attitude adjustment mechanism 120 of FIG. Is driven based on the output control signal of 1., and the relative relationship between the vehicle sensor 110 and the vehicle body 50 is adjusted. The control unit 130 back-calculates the attitude of the attitude adjustment mechanism 120 based on the actual operation stroke or angle of the operation unit 128, and dynamically changes the coordinate system of the vehicle sensor 110. In other words, the present embodiment uses the kinematic and inverse kinematic states of the attitude adjusting mechanism 120 to estimate the current attitude of the vehicle sensor 110.

As shown in FIG. 11, FIG. 11 shows another method for automatically adjusting a sensor for a vehicle shown in FIG. 4, other than the correction method of the sensor for a vehicle 110 using the kinematics and the inverse kinematics of the posture adjusting mechanism 120 described above. It is a flow chart which shows an embodiment. Step S132 is executed, and based on the coordinates of at least one fixing device in the vehicle body 50, the change amount of the relative relationship is obtained from the coordinates of the adjusted vehicle sensor 110. For example, if the fixing device is provided as a fixed sensor and the fixed sensor is a rider and is fixed to a fixed position (vehicle roof 52) of the vehicle body 50 in FIG. 2, the fixed sensor cannot adjust its posture. That is, the fixed sensor and the vehicle body 50 have relative coordinates, and therefore, the amount of change in the relative relationship is derived from the coordinates of the automotive sensor 110 after adjustment based on the coordinates of the fixed sensor. In other words, by using the coordinates of the fixed sensor as reference coordinates, it is possible to know the amount of change in the relative relationship of the automotive sensor 110 after adjustment. For example, the vehicle sensor 110 has coordinates, the height of the vehicle sensor 110 with respect to the vehicle body 50 is the first height, and the height of the fixed sensor with respect to the vehicle body 50 is also the first height. When the second height is reached after the height of the use sensor 110 is adjusted, the second height and the first height become higher. That is, the height of the automobile sensor 110 is higher than the height of the fixed sensor. By this step S132, the amount of change in the relative relationship is obtained from the adjusted coordinates of the vehicle sensor 110, that is, the height distance of the vehicle sensor 110 is subtracted from the height distance of the fixed sensor.

Then, step S134 is executed and the relative positional relationship between the at least one fixing device and the vehicle sensor 110 is corrected. Subsequently, step S136 is executed, and the conversion of the relative relationship between the at least one fixing device and the vehicle sensor 110 is updated. The coordinates of the vehicle sensor 110 are dynamically converted by the above steps S132 to S136. As described above, according to the present invention, the correction is further performed after the attitude of the vehicle sensor 110 is adjusted by another fixing device. In another embodiment, the stationary sensor is combined with the image information module 140 of this embodiment to have corresponding image information. The image information of the fixed type sensor is used as a reference feature, and the relative positional relationship between the fixed type sensor and the vehicle sensor 110 is dynamically corrected by the image information of the vehicle sensor 110 after being compared and adjusted by the control unit 130. It

Summarizing the above, in the automobile sensor automatic adjustment method and its system of the present invention, the posture of the automobile sensor is adjusted based on the adjustment request corresponding to the situation of different traveling environments, and the target object in the specific distance range is adjusted. It is detected and the detection range is no longer blocked by the vehicle body or the shield.

Further, according to the present invention, the situation of the driving environment provided by the image information of the image information module is further combined to judge and adjust the attitude of the vehicle sensor.

Therefore, the embodiments disclosed in the present specification are for explaining the present invention, not for limiting the present invention, and the idea and scope of the present invention are not limited by the embodiments. The scope of the present invention should be construed according to the claims, and all techniques within the scope equivalent thereto should be construed as being included in the scope of the right of the present invention.

40 Obstacle 50 Car body 52 Automobile roof 100 Automobile sensor automatic adjustment system 200 Automobile sensor automatic adjustment system 110 Automobile sensor 112 Detection unit 120 Posture adjustment mechanism 122 Connecting unit 124A First series connecting rod 124B Second connecting rod 125A First drive Part 125B Second drive part 126A First moving part 126B Second moving part 128 Actuating unit 130 Control unit 140 Image information module AC1 Adjustment request AC2 Adjustment request AC3 Adjustment request AC4 Adjustment request AC5 Adjustment request AC6 Adjustment request AC7 Adjustment request AC8 Adjustment request BL reference line C axis CL detection center DT traveling direction DR detection distance E1 traveling environment height E2 speed E3 forward shielding E4 topography change E5 lateral adjustment E6 overtaking execution ES traveling environment situation L vehicle longitudinal direction L1 moving direction L2 First direction L3 Second direction P Posture P1 Posture P2 Posture P3 Posture RL Road S1 First side face S2 Second side face S100 Automotive sensor automatic adjustment method S110 Step S120 Step S130 Step S121 Step S122 Step S123 Step S124 Step S125 Step S126 Step S127 step S128 step S132 step S134 step S136 step S224 step S225 step S226 step S227 step S228 step S321 step S323 step S325 step

Claims (22)

A step of disposing an automotive sensor having an attitude on a vehicle body, wherein the attitude of the vehicle sensor is defined by one of a distance, a tilt angle, and a rotation angle of the vehicle sensor with respect to the vehicle body; The distance of the vehicle sensor with respect to the vehicle body includes the height and position of the vehicle sensor with respect to the vehicle body;
A step of determining whether or not there is an adjustment request based on the situation of the traveling environment of the vehicle body, wherein the situation of the traveling environment includes a single event or a combination of a plurality of events,
And a step of adjusting the posture of the vehicle sensor based on the adjustment request. The situation of the driving environment includes a phenomenon of height of the driving environment,
Determining whether the posture of the vehicle sensor exceeds a height limit of a traveling environment,
When it is determined that the posture of the vehicle sensor exceeds the height limit of the traveling environment, the adjustment request is to lower the height of the vehicle sensor with respect to the vehicle body, The method according to claim 1, further comprising: adapting to a height limit. The situation of the driving environment includes a phenomenon of speed,
A step of determining whether or not the speed of the vehicle body exceeds a set speed range;
When it is determined that the speed of the vehicle body exceeds the set speed range, it is further determined whether the speed of the vehicle body is higher than an upper limit speed value of the set speed range,
If it is determined that the speed of the vehicle body is higher than the upper limit speed value of the set speed range, the adjustment request is to increase the height of the vehicle sensor with respect to the vehicle body,
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value in the set speed range, the adjustment request includes a step of lowering the height of the vehicle sensor with respect to the vehicle body. The automatic sensor adjustment method for an automobile according to claim 1, wherein The situation of the driving environment includes a front shielding event,
A step of determining whether or not the front of the vehicle body is shielded;
When it is determined that the front of the vehicle body is blocked, it is determined whether the speed of the vehicle body is higher than an upper limit speed value of a set speed range,
If it is determined that the speed of the vehicle body is higher than the upper limit speed value of the set speed range, the adjustment request is to lower the height of the vehicle sensor with respect to the vehicle body,
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value in the set speed range, the adjustment request includes a step of lowering the height of the vehicle sensor with respect to the vehicle body. The automatic sensor adjustment method for an automobile according to claim 1, wherein The situation of the driving environment includes a front shielding event,
A step of determining whether or not the front of the vehicle body is shielded;
When it is determined that the front of the vehicle body is shielded, the adjustment request includes a step of adjusting the height of the vehicle sensor with respect to the vehicle body. A method for automatically adjusting a sensor for an automobile as described. The situation of the driving environment includes a phenomenon of speed,
A step of determining whether or not the speed of the vehicle body exceeds a set speed range;
When it is determined that the speed of the vehicle body exceeds the set speed range, it is further determined whether the speed of the vehicle body is higher than an upper limit speed value of the set speed range,
If it is determined that the speed of the vehicle body is higher than the upper limit speed value of the set speed range, the adjustment request is to increase the inclination angle of the vehicle sensor with respect to the vehicle body,
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value of the set speed range, the adjustment request includes a step of lowering the inclination angle of the vehicle sensor with respect to the vehicle body. The automatic sensor adjustment method for an automobile according to claim 1, wherein The situation of the driving environment includes a front shielding event,
A step of determining whether or not the front of the vehicle body is shielded;
If it is determined that the front of the vehicle body is shielded, it is determined whether the speed of the vehicle body is higher than an upper limit speed value of a set speed range,
If it is determined that the speed of the vehicle body is higher than the upper limit speed value of the set speed range, the adjustment request is to lower the tilt angle of the vehicle sensor with respect to the vehicle body,
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value of the set speed range, the adjustment request includes a step of increasing the inclination angle of the vehicle sensor with respect to the vehicle body. The automatic sensor adjustment method for an automobile according to claim 1, wherein The situation of the driving environment includes a front shielding event,
A step of determining whether or not the front of the vehicle body is shielded;
When it is determined that the front of the vehicle body is blocked, the adjustment request includes a step of adjusting an inclination angle of the vehicle sensor with respect to the vehicle body. A method for automatically adjusting a sensor for an automobile as described. The situation of the driving environment includes an event of topographic change,
Determining whether there is a change in the terrain in front of the vehicle body;
Adjusting the posture of the vehicle sensor based on an event of the landform change when it is determined that there is a landform change in front of the vehicle body. 1. The method for automatically adjusting a sensor for an automobile according to 1. The step of determining that there is a change in the terrain in front of the vehicle body,
The step of determining whether there is a change in the slope of the road,
If it is determined that there is a change in the slope of the road, a step of determining whether the slope of the road is uphill or downhill,
When it is determined that the slope of the road is the uphill, the adjustment request is to lower the height of the vehicle sensor with respect to the vehicle body,
10. When it is determined that the slope of the road is the downhill, the adjustment request includes a step of increasing the height of the vehicle sensor with respect to the vehicle body. A method for automatically adjusting a sensor for an automobile as described. The step of determining that there is a change in the terrain in front of the vehicle body,
The step of determining whether there is a change in the slope of the road,
If it is determined that there is a change in the slope of the road, a step of determining whether the slope of the road is uphill or downhill,
When it is determined that the slope of the road is the uphill, the adjustment request is to lower the inclination angle of the vehicle sensor with respect to the vehicle body,
10. When it is determined that the slope of the road is the downhill, the adjustment request includes a step of increasing the inclination angle of the vehicle sensor with respect to the vehicle body. A method for automatically adjusting a sensor for an automobile as described. The step of determining that there is a change in the terrain in front of the vehicle body,
A step of determining whether there is a front intersection or a curve in front of the vehicle body;
When it is determined that there is the front intersection or the curve in front of the vehicle body, the adjustment request includes a step of increasing the height of the vehicle sensor with respect to the vehicle body. The method for automatically adjusting a sensor for an automobile according to claim 9. The step of determining that there is a change in the terrain in front of the vehicle body,
A step of determining whether there is a front intersection or a curve in front of the vehicle body;
When it is determined that there is the front intersection or the curve in front of the vehicle body, the adjustment request includes a step of increasing the inclination angle of the vehicle sensor with respect to the vehicle body. The method for automatically adjusting a sensor for an automobile according to claim 9. The driving environment situation includes a lateral adjustment event,
A step of determining whether or not the front side of the vehicle body is shielded on one side;
When it is determined that the front side of the vehicle body is shielded on one side, a step of determining whether or not the speed of the vehicle body is higher than an upper limit speed value of a set speed range,
When it is determined that the speed of the vehicle body is higher than the upper limit speed value of the set speed range, the adjustment request is to move the rotation angle of the vehicle sensor with respect to the vehicle body in a direction of being shielded. The steps to make adjustments to
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value of the set speed range, the adjustment request is to move the rotation angle of the vehicle sensor with respect to the vehicle body in a direction opposite to the shielded side. The method for automatically adjusting a sensor for a vehicle according to claim 1, further comprising: The driving environment situation further includes an event of overtaking execution,
A step of determining whether overtaking is being performed,
If it is determined that overtaking is being performed, the adjustment request is to perform adjustment so as to move the rotation angle of the vehicle sensor with respect to the vehicle body in the direction of the overtaken side,
If it is determined that overtaking has not been executed, the adjustment request includes a step of adjusting the posture of the vehicle sensor based on an event of the lateral adjustment. The automatic sensor adjustment method for a vehicle according to claim 14. The driving environment situation includes a lateral adjustment event,
A step of determining whether or not the front side of the vehicle body is shielded on one side;
When it is determined that the front side of the vehicle body is shielded on one side, a step of determining whether or not the speed of the vehicle body is higher than an upper limit speed value of a set speed range,
When it is determined that the speed of the vehicle body is higher than the upper limit speed value in the range of the set speed, the adjustment request is to move the position of the vehicle sensor with respect to the vehicle body in the direction of the shielded side. The steps to make adjustments,
If it is determined that the speed of the vehicle body is not higher than the upper limit speed value of the set speed range, it is further determined whether the speed of the vehicle body is lower than the lower limit speed value of the set speed range, When it is determined that the speed of the vehicle body is lower than the lower limit speed value in the set speed range, the adjustment request moves the position of the vehicle sensor with respect to the vehicle body in a direction opposite to the shielded side. The method for automatically adjusting a sensor for an automobile according to claim 1, further comprising the step of: The driving environment situation further includes an event of overtaking execution,
A step of determining whether overtaking is being performed,
If it is determined that overtaking is being performed, the adjustment request is to perform adjustment so as to move the position of the sensor for the vehicle with respect to the vehicle body in the direction of the overtaken side,
If it is determined that overtaking has not been executed, the adjustment request includes a step of adjusting the posture of the vehicle sensor based on an event of the lateral adjustment. The automatic sensor adjustment method for a vehicle according to claim 16. The step of adjusting the posture of the vehicle sensor based on the adjustment request,
The method for automatically adjusting a vehicle sensor according to claim 1, further comprising the step of adjusting the posture of the vehicle sensor by combining image information. The step of adjusting the posture of the vehicle sensor based on the adjustment request,
Acquiring a relative relationship change amount from the coordinate of the adjusted vehicle sensor based on the coordinate of at least one fixing device in the vehicle body,
Correcting the relative positional relationship between the at least one fixing device and the vehicle sensor;
Updating the relative relationship conversion between the at least one fixing device and the vehicle sensor, the method for automatically adjusting a vehicle sensor according to claim 1. A sensor automatic adjustment system for an automobile applied to a vehicle body,
A vehicle sensor having a posture, wherein the posture of the vehicle sensor is defined by one of a distance, a tilt angle, and a rotation angle of the vehicle sensor with respect to the vehicle body. The distance includes the height and position of the vehicle sensor with respect to the vehicle body;
It is connected to the vehicle sensor, determines whether or not an adjustment request is present based on the situation of the driving environment, and determines the vehicle sensor automatic adjustment method based on the adjustment request and outputs a corresponding control signal. 20. The vehicle sensor according to claim 2, wherein the driving environment condition includes a single event or a combination of a plurality of events, and the vehicle sensor automatic adjustment method is the control unit according to any one of claims 2 to 19. It is an automatic adjustment method,
A vehicle sensor automatic adjustment, comprising: a posture adjusting mechanism, which is connected to the vehicle sensor and the control unit, and adjusts the posture of the vehicle sensor based on the control signal of the control unit. system. Is connected to the control unit and is used to provide image information to the control unit, predicts the situation of the traveling environment of the vehicle body based on the image information, and the image information is coupled to the control unit. The automatic sensor adjustment system for a vehicle according to claim 20, further comprising an image information module for determining whether or not the adjustment request is present. 21. The sensor automatic adjustment system for a vehicle according to claim 20, wherein the attitude adjustment mechanism includes a linear adjustment mechanism, a rotation adjustment mechanism, or a combination thereof.

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