JP2020184152A - Adhesion detection device and adhesion detection method - Google Patents

Abstract

To appropriately execute detection of foreign matter adhesion to an object detection sensor.SOLUTION: An adhesion detection device (30) is constituted so as to detect foreign matter adhesion to an object detection sensor. The adhesion detection device comprises an adhesion determination unit (305), an accelerating/decelerating state acquisition unit (303), and a threshold setting unit (304). The adhesion determination unit determines foreign matter adhesion to the object detection sensor, when a count value exceeds an adhesion determination value, the count value corresponding to a duration time in a proximity detection state where a proximity state of the object detection sensor approaching an object approach is detected. The accelerating/decelerating state acquisition unit acquires an accelerating/decelerating state of a vehicle. The threshold setting unit sets the adhesion determination value according to the accelerating/decelerating state acquired by the accelerating/decelerating state acquisition unit.SELECTED DRAWING: Figure 3

Description

The present invention relates to an adhesion detection device and an adhesion detection method for detecting the adhesion of foreign matter to an object detection sensor that detects an object existing around the vehicle.

As the object detection sensor, an ultrasonic sensor, a millimeter wave radar sensor, and the like are used. This type of object detection sensor is used for driving support such as collision avoidance.

Foreign matter such as snow may adhere to such an object detection sensor during traveling. When foreign matter adheres to the object detection sensor, the adhered foreign matter may be erroneously detected as an object for collision avoidance or the like, that is, an obstacle, which may hinder driving support or the like.

In this regard, the apparatus described in Patent Document 1 determines that deposits such as snow are attached to the object detecting means when the predetermined conditions are met. A predetermined condition for determining whether or not it is an deposit is, for example, whether or not the detection time exceeds a predetermined time. The detection time is the time during which the detected object is continuously detected.

JP-A-2015-49665

As described above, this type of object detection sensor is used for driving support such as collision avoidance. Therefore, it is required to more appropriately detect the adhesion of foreign matter to the object detection sensor. The present invention has been made in view of the circumstances exemplified above. That is, the present invention provides, for example, an apparatus and a method capable of more appropriately detecting the adhesion of foreign matter to an object detection sensor.

The adhesion detection device (30) is configured to detect the adhesion of the foreign matter (M) to the object detection sensor (21). The object detection sensor is configured to detect the object existing around the vehicle (10) by transmitting the exploration wave and receiving the received wave including the reflected wave by the object (B) of the exploration wave. Has been done.
The adhesion detection device according to claim 1 is
When the count value corresponding to the duration of the proximity detection state in which the proximity state in which the object detection sensor and the object are close to each other is detected exceeds the adhesion determination threshold value, the adhesion of the foreign matter to the object detection sensor is determined. Adhesion determination unit (305) and
The acceleration / deceleration state acquisition unit (303) that acquires the acceleration / deceleration state of the vehicle, and
A threshold setting unit (304) that sets the adhesion determination threshold value according to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit.
Is equipped with.
The adhesion detection method according to claim 5 is a method for detecting the adhesion of the foreign matter to the object detection sensor, and includes the following procedure:
Acquire the acceleration / deceleration state and
The adhesion determination threshold value is set according to the acquired acceleration / deceleration state.
When the count value exceeds the adhesion determination threshold value, the adhesion of the foreign matter to the object detection sensor is determined.

In each column of the application documents, each element may be given a reference code in parentheses. However, such reference numerals are merely examples of the correspondence between the same element and the specific means described in the embodiments described later. Therefore, the present invention is not limited by the above description of the reference numeral.

It is a schematic block diagram of the vehicle to which the embodiment is applied. It is the schematic which shows the mounting state to the vehicle of the object detection sensor shown in FIG. It is a block diagram which shows an example of the functional structure of the electronic control apparatus shown in FIG. It is the schematic which shows the operation outline of the electronic control apparatus shown in FIG. It is a flowchart which shows one operation example of the electronic control apparatus shown in FIG.

(Embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that if various modifications applicable to one embodiment are inserted in the middle of a series of explanations relating to the embodiment, the understanding of the embodiment may be hindered. Therefore, the modified examples will be described together after the description of the embodiment.

(Constitution)
Referring to FIGS. 1 and 2, the vehicle 10 is a so-called four-wheeled vehicle, and includes a vehicle body 11 having a substantially rectangular shape in a plan view. Hereinafter, a virtual straight line that passes through the center of the vehicle 10 in the vehicle width direction and is parallel to the vehicle total length direction of the vehicle 10 in a plan view is referred to as a vehicle center line LC. The vehicle overall length direction is a direction orthogonal to the vehicle width direction and orthogonal to the vehicle height direction. The vehicle height direction is a direction that defines the vehicle height of the vehicle 10, and is a direction parallel to the direction of gravity action when the vehicle 10 is placed on a horizontal plane. In FIG. 1, the vehicle overall length direction is the vertical direction in the figure, and the vehicle width direction is the horizontal direction in the figure.

“Front”, “rear”, “left”, and “right” in the vehicle 10 are defined as indicated by arrows in FIG. That is, the vehicle overall length direction is synonymous with the front-rear direction. Further, the vehicle width direction is synonymous with the left-right direction. The shape of each part of the vehicle 10 in the "planar view" refers to the shape when the vehicle 10 is placed on a horizontal plane and the respective parts are viewed from vertically above the vehicle 10 with a line of sight in the same direction as the direction of gravity action. ..

A front bumper 12 is attached to the front end of the vehicle body 11. A rear bumper 13 is attached to the rear end of the vehicle body 11. A door panel 14 is attached to a side surface portion of the vehicle body 11. In the specific example shown in FIG. 1, a total of four door panels 14 are provided, two on each side. A door mirror 15 is attached to each of the pair of left and right door panels 14 on the front side.

The vehicle 10 is equipped with a driving support system 20. The vehicle 10 equipped with the driving support system 20 according to the present embodiment may be hereinafter referred to as "own vehicle 10". The driving support system 20 is configured to execute a driving support operation in the own vehicle 10 by being mounted on the own vehicle 10. Specifically, the driving support system 20 is provided with an object detection sensor 21. That is, the driving support system 20 detects the object B existing around the own vehicle 10 by using the object detection sensor 21, and executes the driving support operation according to the detection result of the object B. .. The driving support operation using the object detection result realized by the driving support system 20 is, for example, at least one of false start suppression, false acceleration suppression, collision avoidance, automatic follow-up running, parking support, and the like.

The object detection sensor 21 is configured to detect the object B by transmitting the exploration wave to the outside and receiving the received wave including the reflected wave by the object B of the exploration wave. Specifically, the object detection sensor 21 is a so-called ultrasonic sensor, which is configured to transmit an exploration wave which is an ultrasonic wave and to be able to receive a received wave including an ultrasonic wave. Further, the object detection sensor 21 is configured to generate and output an output signal corresponding to the reception result of the received wave.

In the present embodiment, the object detection sensor 21 is a distance measuring sensor that detects the distance from the object B, and is provided so as to generate and output an output signal including the distance measuring information. The distance measurement information is information included in the output signal of the object detection sensor 21, and is information corresponding to the distance to the object B around the own vehicle 10.

The term "reception" of the received wave as used herein means receiving the received wave to the extent that the distance measurement information can be effectively acquired. Therefore, reception with a weak reception strength to the extent that distance measurement information cannot be effectively acquired is not treated as “reception” here. Therefore, "reception" referred to here can be paraphrased as "reception above the threshold reception intensity", "effective reception", or "good reception".

The driving support system 20 includes a plurality of object detection sensors 21. That is, a plurality of object detection sensors 21 are mounted on the own vehicle 10. Each of the plurality of object detection sensors 21 is provided at different positions in a plan view. Further, in the present embodiment, each of the plurality of object detection sensors 21 is arranged so as to shift from the vehicle center line LC to any one side in the vehicle width direction.

In the present embodiment, two object detection sensors 21 are provided on the front surface of the vehicle body 11. Specifically, the front bumper 12 is equipped with a first front sonar 21F1 and a second front sonar 21F2 as object detection sensors 21. Similarly, two object detection sensors 21 are provided on the rear surface of the vehicle body 11. Specifically, the rear bumper 13 is equipped with a first rear sonar 21R1 and a second rear sonar 21R2 as object detection sensors 21.

“Direct wave” and “indirect wave” are defined as follows. One of the plurality of object detection sensors 21 is referred to as a "first ranging sensor", and the other one is referred to as a "second ranging sensor". The received wave in the first ranging sensor and caused by the reflected wave of the exploration wave transmitted from the first ranging sensor by the object B is referred to as a "direct wave". The direct wave is typically the received wave when the first ranging sensor receives the reflected wave of the exploration wave transmitted from the first ranging sensor by the object B as a received wave. That is, the direct wave is the received wave when the object detection sensor 21 that transmits the exploration wave and the object detection sensor 21 that receives the reflected wave of the exploration wave by the object B as the received wave are the same. ..

On the other hand, the received wave in the second ranging sensor and caused by the reflected wave of the exploration wave transmitted from the first ranging sensor by the object B is referred to as an "indirect wave". The indirect wave is typically the received wave when the second ranging sensor receives the reflected wave of the exploration wave transmitted from the first ranging sensor by the object B as a received wave. That is, the indirect wave is the received wave when the object detection sensor 21 that transmits the exploration wave and the object detection sensor 21 that receives the reflected wave of the exploration wave by the object B as the received wave are different.

FIG. 1 shows a direct wave region RD and an indirect wave region RI in two object detection sensors 21 by taking the first front sonar 21F1 and the second front sonar 21F2 as examples. The direct wave region RD is a region in which the direct wave caused by the object B can be received when the object B is present. The indirect wave region RI is a region in which an indirect wave caused by the object B can be received when the object B is present. Specifically, the indirect wave region RI does not completely coincide with the region where the direct wave regions RDs of the two object detection sensors 21 overlap each other, but most of them overlap. Hereinafter, for the sake of simplification of the description, the indirect wave region RI is treated as assuming that the direct wave region RDs of the two object detection sensors 21 substantially coincide with the overlapping region.

The first front sonar 21F1 is provided on the left side of the vehicle center line LC on the front surface of the front bumper 12 so as to transmit the exploration wave to the left front of the own vehicle 10. The second front sonar 21F2 is provided on the right side of the vehicle center line LC on the front surface of the front bumper 12 so as to transmit the exploration wave to the right front of the own vehicle 10. The first front sonar 21F1 and the second front sonar 21F2 are arranged symmetrically with respect to the vehicle center line LC in a plan view.

As described above, the first front sonar 21F1 and the second front sonar 21F2 are arranged at different positions in a plan view. Further, the first front sonar 21F1 and the second front sonar 21F2, which are adjacent to each other in the vehicle width direction, have a positional relationship in which the reflected wave of the exploration wave transmitted by one of them can be received as a received wave of the other. It is provided. That is, the first front sonar 21F1 is arranged so as to be able to receive both the direct wave corresponding to the exploration wave transmitted by itself and the indirect wave corresponding to the exploration wave transmitted by the second front sonar 21F2. Similarly, the second front sonar 21F2 is arranged so as to be able to receive both a direct wave corresponding to the exploration wave transmitted by itself and an indirect wave corresponding to the exploration wave transmitted by the first front sonar 21F1.

The first rear sonar 21R1 is provided on the left side of the vehicle center line LC on the rear surface of the rear bumper 13 so as to transmit the exploration wave to the left rear of the own vehicle 10. The second rear sonar 21R2 is provided on the right side of the vehicle center line LC on the rear surface of the rear bumper 13 so as to transmit the exploration wave to the right rear of the own vehicle 10. The first rear sonar 21R1 and the second rear sonar 21R2 are arranged symmetrically with respect to the vehicle center line LC in a plan view.

As described above, the first rear sonar 21R1 and the second rear sonar 21R2 are arranged at different positions in a plan view. Further, the first rear sonar 21R1 and the second rear sonar 21R2, which are adjacent to each other in the vehicle width direction, are provided in a positional relationship in which the reflected wave of the exploration wave transmitted by one of them by the object B can be received as a received wave of the other. ing. That is, the first rear sonar 21R1 is arranged so as to be able to receive both the direct wave corresponding to the exploration wave transmitted by itself and the indirect wave corresponding to the exploration wave transmitted by the second rear sonar 21R2. Similarly, the second rear sonar 21R2 is arranged so as to be able to receive both the direct wave corresponding to the exploration wave transmitted by itself and the indirect wave corresponding to the exploration wave transmitted by the first rear sonar 21R1.

FIG. 2 shows a state in which the object detection sensor 21 is mounted on the front bumper 12. As shown in FIG. 2, the object detection sensor 21 includes a sensor casing 21A and an ultrasonic microphone 21B.

The sensor casing 21A is a component that constitutes the casing of the object detection sensor 21, and is made of synthetic resin or the like. The ultrasonic microphone 21B has a configuration in which an electro-mechanical conversion element such as a piezoelectric element is housed inside a bottomed cylindrical microphone case made of a metal such as aluminum. That is, the ultrasonic microphone 21B has a substantially cylindrical outer shape surrounding the directional central axis DA. The directional central axis DA is a virtual straight line extending from the object detection sensor 21, which is an ultrasonic sensor, along the transmission / reception direction of ultrasonic waves, and serves as a reference for the directional angle. The "directed central axis" can also be referred to as the detection axis.

The ultrasonic microphone 21B has a transmission / reception surface 21C. The transmission / reception surface 21C is a substantially circular bottom surface or top surface of the substantially cylindrical outer shape of the ultrasonic microphone 21B, and is formed in a plane shape with the directional central axis DA as a normal. That is, the ultrasonic microphone 21B is configured to oscillate a search wave by ultrasonically vibrating the transmission / reception surface 21C based on the drive signal applied to the electro-mechanical conversion element. Further, the ultrasonic microphone 21B is configured so that the electric-mechanical conversion element generates a received signal which is an electric signal corresponding to the excitation state of the transmission / reception surface 21C by the ultrasonic wave received from the outside.

The sensor casing 21A has a microphone accommodating portion 21D and a casing main body portion 21E. The microphone accommodating portion 21D is formed in a substantially cylindrical shape surrounding the directional central axis DA so as to accommodate the ultrasonic microphone 21B in a state where the transmission / reception surface 21C of the ultrasonic microphone 21B is exposed to the outside. The tip of the microphone accommodating portion 21D that exposes the transmission / reception surface 21C of the ultrasonic microphone 21B to the outside is inserted into the mounting hole H which is a through hole formed in the front bumper 12. That is, the transmission / reception surface 21C of the ultrasonic microphone 21B is exposed at the mounting hole H toward the outer space of the vehicle body 11. The casing main body 21E is formed in a box shape having a substantially rectangular parallelepiped shape. Inside the casing main body 21E, a circuit board on which circuit elements for executing output of a drive signal, processing of a received signal, and the like are mounted is housed.

Referring to FIG. 1 again, the vehicle 10 is equipped with a plurality of sensors including a vehicle speed sensor 22, a shift position sensor 23, an accelerator pedal sensor 24, and a brake pedal sensor 25. Further, the vehicle 10 is equipped with a display unit 26 and an alarm sound generation unit 27. Further, the driving support system 20 includes a driving support ECU 30. ECU is an abbreviation for Electronic Control Unit. Further, the vehicle 10 is equipped with a drive system ECU 40 and a braking system ECU 50. For the sake of simplification of the illustration, the electrical connection relationship between the parts is appropriately omitted in FIG.

Each of the plurality of object detection sensors 21 is connected to the driving support ECU 30 so as to be capable of information communication. That is, each of the plurality of object detection sensors 21 is provided so as to transmit and receive ultrasonic waves under the control of the driving support ECU 30. Further, each of the plurality of object detection sensors 21 transmits an output signal corresponding to the detection result of the received wave to the driving support ECU 30. In the present embodiment, each of the plurality of object detection sensors 21 is electrically connected to the driving support ECU 30 by an information communication cable.

The vehicle speed sensor 22, the shift position sensor 23, the accelerator pedal sensor 24, and the brake pedal sensor 25 are connected to the driving support ECU 30 so as to be capable of information communication. In the present embodiment, the vehicle speed sensor 22, the shift position sensor 23, the accelerator pedal sensor 24, and the brake pedal sensor 25 are electrically connected to the driving support ECU 30 by an information communication cable.

The vehicle speed sensor 22 is provided so as to generate a signal corresponding to the traveling speed of the own vehicle 10 and transmit it to the driving support ECU 30. The traveling speed of the own vehicle 10 is hereinafter simply referred to as "vehicle speed". The shift position sensor 23 is provided so as to generate a signal corresponding to the shift position of the own vehicle 10 and transmit it to the driving support ECU 30.

The accelerator pedal sensor 24 is provided so as to generate a signal corresponding to an operating state of the accelerator pedal (not shown) and transmit it to the driving support ECU 30. The brake pedal sensor 25 is provided so as to generate a signal corresponding to an operating state of a brake pedal (not shown) and transmit it to the driving support ECU 30.

The display unit 26 and the alarm sound generation unit 27 are arranged in the vehicle interior of the own vehicle 10. The display unit 26 is connected to the driving support ECU 30 in an information communication manner so as to perform various displays related to object detection and driving support under the control of the driving support ECU 30. The alarm sound generation unit 27 is connected to the driving support ECU 30 in an information communication manner so as to generate various alarm sounds related to object detection and driving support under the control of the driving support ECU 30. In the present embodiment, the driving support ECU 30 is electrically connected to the display unit 26 and the alarm sound generating unit 27 by an information communication cable.

The driving support ECU 30 is an electronic control device that controls the overall operation of the driving support system 20, and is arranged inside the vehicle body 11. The operation support ECU 30 is connected to the drive system ECU 40 and the braking system ECU 50 so as to be capable of information communication. In the present embodiment, the driving support ECU 30 is electrically connected to the drive system ECU 40 and the braking system ECU 50 by an information communication cable.

The drive system ECU 40 is configured to control the drive of a vehicle drive system (for example, an engine and / or a motor) (not shown). The braking system ECU 50 is configured to control the operation of a vehicle braking system (that is, a brake) (not shown).

The driving support ECU 30 is configured to execute a predetermined operation based on signals and information received from a plurality of sensors including the object detection sensor 21. The "predetermined operation" includes an object detection operation using the object detection sensor 21 and a driving support operation of the own vehicle 10 based on the object detection result which is the result of the object detection operation. Further, the driving support ECU 30 that functions as the “adhesion detection device” is configured to detect the adhesion of the foreign matter M to each of the plurality of object detection sensors 21.

In the present embodiment, the driving support ECU 30 is a so-called in-vehicle microcomputer, and includes a CPU (ROM), a non-volatile rewritable memory, a RAM, an input / output interface, and the like (not shown). CPU is an abbreviation for Central Processing Unit. ROM is an abbreviation for Read Only Memory. The non-volatile rewritable memory is, for example, EPROM, EEPROM, flash memory, or the like. EPROM is an abbreviation for Erasable Programmable Read Only Memory. EEPROM is an abbreviation for Electrically Erasable Programmable Read Only Memory. RAM is an abbreviation for Random access memory. ROM, non-volatile rewritable memory, and RAM are non-transitional substantive storage media. The CPU, ROM, RAM and non-volatile rewritable memory of the operation support ECU 30 are hereinafter abbreviated as "CPU", "ROM", "RAM" and "non-volatile RAM".

The operation support ECU 30 is configured so that various control operations can be realized by the CPU reading a program from the ROM or the non-volatile RAM and executing the program. Further, various data used when executing the program are stored in advance in the ROM or the non-volatile RAM. The various data are, for example, initial values, look-up tables, maps, and the like.

As shown in FIG. 3, the driving support ECU 30 has the following parts as a functional configuration realized by the in-vehicle microcomputer. That is, the driving support ECU 30 includes a vehicle information acquisition unit 301, a distance measurement information acquisition unit 302, an acceleration / deceleration state acquisition unit 303, a threshold value setting unit 304, an adhesion determination unit 305, and a fail-safe control unit 306. doing. Hereinafter, the functional configuration of the driving support ECU 30 shown in FIG. 3 will be described.

The vehicle information acquisition unit 301 is provided so as to acquire vehicle information which is information on the driving state of the own vehicle 10. That is, the vehicle information acquisition unit 301 acquires the vehicle speed of the own vehicle 10 based on the output of the vehicle speed sensor 22. Further, the vehicle information acquisition unit 301 acquires the shift position of the own vehicle 10 based on the output of the shift position sensor 23. Further, the vehicle information acquisition unit 301 acquires the accelerator operation amount of the own vehicle 10 based on the output of the accelerator pedal sensor 24. Further, the vehicle information acquisition unit 301 acquires the brake pedal operation amount of the own vehicle 10 based on the output of the brake pedal sensor 25.

The distance measurement information acquisition unit 302 is provided so as to acquire sonar detection information which is information (for example, distance measurement information) included in the output signal of the object detection sensor 21. Specifically, the distance measurement information acquisition unit 302 holds the sonar detection information acquired from each of the plurality of object detection sensors 21 in chronological order for a predetermined time from the latest information.

The acceleration / deceleration state acquisition unit 303 is provided so as to acquire the acceleration / deceleration state of the own vehicle 10 based on the vehicle information acquired by the vehicle information acquisition unit 301. Specifically, the acceleration / deceleration state acquisition unit 303 determines whether or not the own vehicle 10 is in the high acceleration / deceleration state based on the vehicle speed change, the accelerator operation amount, and the brake pedal operation amount. .. The "high acceleration / deceleration state" is typically a state in which the amount of change in vehicle speed per unit time exceeds a predetermined amount.

The threshold value setting unit 304 sets the adhesion determination threshold value TH according to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit 303. The adhesion determination threshold value TH is a reference value used for determining foreign matter adhesion in the adhesion determination unit 305.

Specifically, the threshold value setting unit 304 sets the adhesion determination threshold value TH to the first adhesion determination threshold value TH1 in the first state in which the acceleration / deceleration state is different from the high acceleration / deceleration state. The first adhesion determination threshold TH1 is set to correspond to a predetermined first duration TT1 (for example, 3 seconds) in the proximity duration TT. The “proximity duration TT” is the duration of the proximity detection state in which the proximity state in which the object detection sensor 21 and the object B are close to each other is detected. The "proximity state" is a state in which the object B exists within a predetermined threshold distance (for example, 40 cm) from the transmission / reception surface 21C of the object detection sensor 21. On the other hand, the threshold value setting unit 304 sets the adhesion determination threshold value TH to the second adhesion determination threshold value TH2 in the second state in which the acceleration / deceleration state is the high acceleration / deceleration state. The second adhesion determination threshold TH2 is set to correspond to a predetermined second duration TT2 (for example, 1.5 seconds) in the proximity duration TT. That is, the second adhesion determination threshold TH2 is set so that the corresponding proximity duration TT is shorter than the first adhesion determination threshold TH1.

The adhesion determination unit 305 is adapted to determine that foreign matter M is attached to the object detection sensor 21 when the count value T corresponding to the proximity duration TT exceeds the adhesion determination threshold TH. The count value T is, for example, the count value of a timer or a counter.

The adhesion determination unit 305 has a proximity determination unit 351 and a counting unit 352. The proximity determination unit 351 is adapted to determine that it is in the proximity detection state when a predetermined proximity detection condition is satisfied. In the present embodiment, the proximity detection condition includes a first condition and a second condition. The first condition is that the detection distance corresponding to the distance measurement information, which is the detection result of the distance to the object B, is equal to or less than the above threshold distance (for example, 40 cm). The second condition is that the indirect wave is not received by the object detection sensor 21 that has detected such a detection distance. That is, the second condition corresponds to the detection distance corresponding to the first condition being detected only by the direct wave. Specifically, the establishment of the proximity detection condition is the establishment of the first condition and the establishment of the second condition.

The counting unit 352 acquires, that is, calculates the counting value T. Specifically, the counting unit 352 counts up the count value T while the proximity detection condition is satisfied, and resets the count value T when the proximity detection condition is not satisfied. Further, the counting unit 352 determines that the foreign matter M is attached to the object detection sensor 21 when the counting value T exceeds the adhesion determination threshold value TH.

The fail-safe control unit 306 is adapted to execute a fail-safe operation, which is one of the driving support operations, based on the acquired vehicle information and sonar detection information and the determination result by the adhesion determination unit 305. The fail-safe operation is, for example, an operation of suppressing an erroneous start due to an erroneous depression of the accelerator pedal and the brake pedal. Alternatively, the fail-safe operation is, for example, an operation of suppressing erroneous acceleration when the accelerator pedal operation amount suddenly increases while the own vehicle 10 is in close proximity to the vehicle in front. Specifically, the fail-safe control unit 306 transmits a control signal for suppressing erroneous start or erroneous acceleration to the drive system ECU 40 and the braking system ECU 50 when the above erroneous operation occurs. It has become.

(Outline of operation)
Hereinafter, an outline of the operation of the driving support system 20 having the above configuration will be described with reference to each figure together with the effects produced by the configuration.

The vehicle information acquisition unit 301 in the driving support ECU 30 acquires vehicle information including the vehicle speed and the shift position. When the predetermined object detection condition is satisfied, the driving support ECU 30 starts the object detection operation using the object detection sensor 21. The object detection condition includes, for example, that the traveling speed of the own vehicle 10 is within a predetermined range, that the shift position of the own vehicle 10 is a traveling position including backward movement, and the like. When the object detection condition is not satisfied, the driving support ECU 30 ends the object detection operation.

During the object detection operation, each of the plurality of object detection sensors 21 repeatedly executes the search wave transmission operation and the reception wave reception operation to generate and output an output signal according to the reception state of the reception wave. The distance measurement information acquisition unit 302 in the driving support ECU 30 acquires sonar detection information including the distance measurement information from each of the plurality of object detection sensors 21. The driving support ECU 30 detects the object B based on the acquired vehicle information and sonar detection information. That is, the driving support ECU 30 calculates the distance of the object B corresponding to the received wave from the own vehicle 10 and the relative position with respect to the own vehicle 10.

When a proximity state in which the object detection sensor 21 and the object B are close to each other actually occurs, the object detection sensor 21 outputs distance measurement information corresponding to the proximity state. Specifically, for example, the proximity state is a state in which the object B exists within a distance of 40 cm from the transmission / reception surface 21C of the object detection sensor 21. Further, in the proximity state, the direct wave can be received by the object detection sensor 21, but the indirect wave cannot be received. That is, in the actual proximity state, the object detection sensor 21 acquires distance measurement information indicating that the object B exists within a distance of 40 cm from the transmission / reception surface 21C by the direct wave.

Foreign matter M such as snow may adhere to the transmission / reception surface 21C of the object detection sensor 21. In this case, the object detection sensor 21 in which the foreign matter M is attached to the transmission / reception surface 21C outputs the distance measurement information corresponding to the close state even if the close state is not actually generated due to the foreign matter M attached. ..

While the actual proximity state can occur for a short time (for example, within 1 second) while the own vehicle 10 is traveling, it cannot usually continue for a longer time. Therefore, it is possible to determine whether or not the proximity detection state is due to the adhesion of the foreign matter M depending on whether or not the proximity duration TT exceeds a predetermined duration threshold value. The proximity duration TT is the duration of the proximity detection state in which the proximity state in which the object detection sensor 21 and the object B are close to each other is detected.

Therefore, the adhesion determination unit 305 determines the adhesion of the foreign matter M to the object detection sensor 21 when the count value T corresponding to the duration of the proximity detection state exceeds the adhesion determination threshold TH. Specifically, the proximity determination unit 351 determines whether or not it is in the proximity detection state based on the vehicle information and the sonar detection information. Further, the counting unit 352 counts up the counting value T while the proximity detection state continues. Then, the counting unit 352 determines the adhesion of the foreign matter M to the object detection sensor 21 when the counting value T exceeds the adhesion determination threshold TH corresponding to the duration threshold value.

In the offset vehicle follow-up driving mode as shown in FIG. 4, there is a concern that a false detection may occur in the foreign matter adhesion detection. The "offset vehicle follow-up travel mode" is a travel mode that follows the offset vehicle V, which is another vehicle existing diagonally in front of the own vehicle 10.

That is, as shown in FIG. 4, for the offset vehicle V in front of the right, the reflected wave of the exploration wave transmitted from the first front sonar 21F1 is not received by the second front sonar 21F2. On the other hand, the reflected wave of the exploration wave transmitted from the second front sonar 21F2 is satisfactorily received by the second front sonar 21F2. As described above, with respect to the offset vehicle V, since only the direct wave is received but the indirect wave is not received, the proximity detection state is likely to continue even if the foreign matter M does not adhere. Therefore, in the offset vehicle follow-up travel mode, it is preferable to suppress the erroneous determination of foreign matter adhesion by extending the determination time of foreign matter adhesion by setting the adhesion determination threshold value TH to a large value.

On the other hand, in the normal traveling state in which the offset vehicle V does not exist, the situation is different from the offset vehicle following traveling mode. Specifically, at the time of high acceleration / deceleration, the vehicle speed deviates from the predetermined range constituting the object detection condition, so that the transmission / reception operation of the object detection sensor 21 is stopped before the determination of foreign matter adhesion is completed. It is possible. Therefore, at the time of high acceleration / deceleration, it is necessary to complete the determination of foreign matter adhesion before the vehicle speed deviates from the predetermined range. That is, at the time of high acceleration / deceleration, it is not preferable to extend the determination time for foreign matter adhesion by setting the adhesion determination threshold value TH to a large value.

Therefore, in the present embodiment, the driving support ECU 30 sets the adhesion determination threshold value TH for determining foreign matter adhesion according to the acceleration / deceleration state of the own vehicle 10. That is, the acceleration / deceleration state acquisition unit 303 acquires the acceleration / deceleration state of the vehicle 10 based on the vehicle information acquired by the vehicle information acquisition unit 301. The threshold value setting unit 304 sets the adhesion determination threshold value TH according to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit 303.

Specifically, the threshold value setting unit 304 sets the adhesion determination threshold value TH to the first adhesion determination threshold value TH1 in the first state in which the acceleration / deceleration state is different from the high acceleration / deceleration state. The first adhesion determination threshold TH1 corresponds to a predetermined first duration TT1 (for example, 3 seconds) in the proximity duration TT. On the other hand, the threshold value setting unit 304 sets the adhesion determination threshold value TH to the second adhesion determination threshold value TH2 in the second state in which the acceleration / deceleration state is the high acceleration / deceleration state. The second adhesion determination threshold TH2 corresponds to a predetermined second duration TT2 (for example, 1.5 seconds) in the proximity duration TT. That is, the second adhesion determination threshold TH2 is set so that the corresponding proximity duration TT is shorter than the first adhesion determination threshold TH1.

According to the present embodiment, in the offset vehicle following travel mode in which acceleration / deceleration is performed relatively slowly, the adhesion determination threshold value TH is set to the first adhesion determination threshold value TH1. As a result, by setting the adhesion determination threshold value TH to a large value and extending the determination time for foreign matter adhesion, it is possible to suppress erroneous determination of foreign matter adhesion.

On the other hand, at the time of high acceleration / deceleration, the adhesion determination threshold value TH is set to the second adhesion determination threshold value TH2. As a result, the foreign matter adhesion determination can be performed quickly by setting the adhesion determination threshold value TH to a small value and shortening the foreign matter adhesion determination time. That is, the occurrence of a problem that the start or acceleration / deceleration is erroneously suppressed by erroneously detecting the attached foreign matter M as the object B can be suppressed as much as possible.

As described above, according to the present embodiment, the adhesion determination threshold value TH for determining the presence or absence of foreign matter adhesion in the object detection sensor 21 is set according to the acceleration / deceleration state of the own vehicle 10. Therefore, it is possible to more appropriately detect the adhesion of the foreign matter M to the object detection sensor 21.

By the way, in recent years, accidents in which the vehicle 10 rushes into the store from the parking space of the store due to a mistake in pressing the accelerator pedal and the brake pedal have frequently occurred. In order to prevent such an accident, a driving support system 20 including an object detection sensor 21 for detecting an object B existing around the vehicle 10 is already installed in the vehicle 10 as standard equipment at the time of shipment from the factory. It is recommended to keep it.

However, such a vehicle 10 already equipped with the driving support system 20 at the time of shipment from the factory is still in widespread use at the time of filing the application of the present application. Therefore, there is a demand that the driving support system 20 including the object detection sensor 21 be mounted on the vehicle 10 by "retrofitting" after shipment from the factory. "After factory shipment" includes after new car sales. That is, there is a request that the driving support system 20 be mounted on the vehicle 10 at a new car dealer, a used car dealer, an automobile accessory store, or the like.

In the standard-equipped driver assistance system 20 mounted on the vehicle 10 at the time of shipment from the factory, four object detection sensors 21 are usually mounted on the front bumper 12, unlike the configuration shown in FIG. The rear bumper 13 is also equipped with four object detection sensors 21. Further, the driving support ECU 30 and various sensors are connected to each other via an in-vehicle network conforming to a predetermined communication standard such as CAN. CAN is an internationally registered trademark and is an abbreviation for Controller Area Network.

On the other hand, in the case of "retrofitting", as shown in FIG. 1, the number of object detection sensors 21 mounted on the front bumper 12 and the rear bumper 13 is set to two for cost reduction and the like. Sometimes. Then, with respect to the offset vehicle V as shown in FIG. 4, a state in which only the direct wave is received but the indirect wave is not received is more likely to occur than in the case of the standard equipment. For this reason, erroneous determination of foreign matter adhesion is more likely to occur than in the case of standard equipment.

Further, the driving support ECU 30 and various sensors cannot be connected via the in-vehicle network as described above, and must be directly electrically connected by using wiring. Therefore, the vehicle information that can be used by the driving support ECU 30 is more limited than that of the standard equipment, and the accuracy is also lowered.

In this respect, in the present embodiment, the adhesion determination threshold value TH is set according to the acceleration / deceleration state of the own vehicle 10, so that the accuracy of determining foreign matter adhesion is improved. Therefore, even in the case of "retrofitting", it is possible to more appropriately detect the adhesion of the foreign matter M.

(Operation example)
Hereinafter, a specific operation example according to the configuration of the present embodiment will be described with reference to the flowchart shown in FIG. For simplification of the illustration, "step" is simply abbreviated as "S" in FIG.

First, in step 501, the driving support ECU 30 acquires vehicle information. The process of step 501 corresponds to the operation of the vehicle information acquisition unit 301. Next, in step 502, the driving support ECU 30 acquires sonar detection information. The process of step 502 corresponds to the operation of the distance measurement information acquisition unit 302.

Subsequently, in step 503, the driving support ECU 30 acquires the acceleration / deceleration state of the own vehicle 10 and determines whether or not the acquired acceleration / deceleration state is a high acceleration / deceleration state. The process of step 503 corresponds to the operation of the acceleration / deceleration state acquisition unit 303. After that, the driving support ECU 30 executes the process of step 504 or step 505 according to the determination result in step 503, and then advances the process to step 506.

When the acceleration / deceleration state is not the high acceleration / deceleration state (that is, step 503 = NO), the driving support ECU 30 executes the process of step 504 and then advances the process to step 506. In step 504, the operation support ECU 30 sets the adhesion determination threshold value TH to the first adhesion determination threshold value TH1. The process of step 504 corresponds to the operation of the threshold setting unit 304.

When the acceleration / deceleration state is the high acceleration / deceleration state (that is, step 503 = YES), the driving support ECU 30 executes the process of step 505 and then advances the process to step 506. In step 505, the operation support ECU 30 sets the adhesion determination threshold value TH to the second adhesion determination threshold value TH2. The process of step 505 corresponds to the operation of the threshold setting unit 304.

In step 506, the driving support ECU 30 determines whether or not the count value T corresponding to the proximity duration TT exceeds the adhesion determination threshold value TH. The process of step 506 corresponds to the operation of the adhesion determination unit 305.

When the count value T exceeds the adhesion determination threshold TH (that is, step 506 = YES), the driving support ECU 30 temporarily ends the process of this flowchart after executing the process of step 507. In step 507, the driving support ECU 30 determines that the foreign matter M is attached to the object detection sensor 21. The process of step 507 corresponds to the operation of the adhesion determination unit 305.

When the count value T is equal to or less than the adhesion determination threshold value TH (that is, step 506 = NO), the operation support ECU 30 advances the process to step 508. In step 508, the driving support ECU 30 determines whether or not the count value C corresponding to the duration of failure of the proximity detection condition exceeds the release determination threshold value CH. The process of step 508 corresponds to the operation of the adhesion determination unit 305.

When the count value C is equal to or less than the release determination threshold value CH (that is, step 508 = NO), the driving support ECU 30 skips the process of step 509 and temporarily ends the process of this flowchart. On the other hand, when the count value C exceeds the release determination threshold value CH (that is, step 508 = YES), the driving support ECU 30 temporarily ends the process of this flowchart after executing the process of step 509. In step 509, the driving support ECU 30 cancels the determination that the foreign matter M has adhered to the object detection sensor 21.

(Modification example)
The present invention is not limited to the above embodiment. Therefore, the above embodiment can be changed as appropriate. A typical modification will be described below. In the following description of the modified example, the differences from the above-described embodiment will be mainly described. Further, in the above-described embodiment and the modified example, the same or equal parts are designated by the same reference numerals. Therefore, in the following description of the modified example, the description in the above embodiment may be appropriately incorporated with respect to the components having the same reference numerals as those in the above embodiment, unless there is a technical contradiction or a special additional explanation.

The present invention is not limited to the specific device configuration shown in the above embodiment. That is, for example, the vehicle 10 is not limited to a four-wheeled vehicle. Specifically, the vehicle 10 may be a three-wheeled vehicle, or a six-wheeled or eight-wheeled vehicle such as a freight truck. There are no particular restrictions on the shape and structure of the details of the vehicle body 11, including the number of door panels 14.

The driving support system 20 may be simply an obstacle detection system. That is, the driving support system 20 may not be able to execute any of false start suppression, false acceleration suppression, collision avoidance, automatic follow-up running, parking support, and the like.

There are no particular restrictions on the structure and type of the object detection sensor 21. That is, for example, the object detection sensor 21 as an ultrasonic sensor may be a so-called ultrasonic sensor array in which transmission / reception elements are arrayed. Alternatively, the object detection sensor 21 may be a type of sensor other than the ultrasonic sensor, such as a millimeter wave radar sensor. There are no particular restrictions on the arrangement and number of object detection sensors 21.

The arrangement of the components that function as the "adhesion detection device" is not limited to the driving support ECU 30. Specifically, for example, all or part of the vehicle information acquisition unit 301, the distance measurement information acquisition unit 302, the acceleration / deceleration state acquisition unit 303, the threshold value setting unit 304, the adhesion determination unit 305, and the fail-safe control unit 306. May be provided in the object detection sensor 21. That is, the object detection sensor 21 may be configured to be able to self-diagnose the presence or absence of foreign matter M adhering to itself.

The present invention is not limited to the specific operation examples and processing modes shown in the above embodiments. That is, for example, as is clear from the description of the above modification, one object detection sensor 21 may be provided on each of the front surface portion and the rear surface portion of the vehicle body 11. In this case, there is no indirect wave in the object detection operation. Therefore, in this case, the second condition that the indirect wave is not received is not used in the proximity detection condition.

The "high acceleration / deceleration state" may refer to a state in which the accelerator operation amount, the brake pedal operation amount, or the change amount of the operation amount per unit time exceeds a predetermined amount. Alternatively, the "high acceleration / deceleration state" may also refer to a state in which the amount of change in vehicle speed per unit time exceeds a predetermined amount.

The establishment of the proximity detection condition may be the establishment of the first condition or the establishment of the second condition.

As described above, the proximity state is a state in which the object B exists within a predetermined threshold distance (for example, 40 cm) from the transmission / reception surface 21C of the object detection sensor 21. Therefore, when the vehicle is actually in close proximity, high acceleration / deceleration is not possible except for an erroneous operation due to an erroneous depression of the accelerator pedal and the brake pedal. Therefore, in the high acceleration / deceleration state, the second condition that the indirect wave is not received may be excluded from the proximity detection condition as long as the distance measurement information corresponding to the proximity state is obtained.

Therefore, the proximity determination unit 351 may determine that it is in the proximity detection state when the proximity detection condition corresponding to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit 303 is satisfied. In this case, the proximity detection condition includes the first condition and the second condition when the acceleration / deceleration state is the first state, and includes the first condition and the second condition when the acceleration / deceleration state is the second state. It is set not to.

In such a configuration, the proximity determination unit 351 in the adhesion determination unit 305 changes the proximity detection condition according to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit 303. That is, when the acceleration / deceleration state is the first state different from the high acceleration / deceleration state, the proximity detection condition includes the first condition and the second condition. On the other hand, in the case of the second state in which the acceleration / deceleration state is the high acceleration / deceleration state, the proximity detection condition includes the first condition but does not include the second condition. Then, the proximity determination unit 351 determines that the proximity detection state is satisfied when the proximity detection condition set according to the acceleration / deceleration state is satisfied.

Specifically, for example, when the acceleration / deceleration state is the first state different from the high acceleration / deceleration state, the proximity determination unit 351 is in the proximity detection state when the first condition and the second condition are satisfied. judge. On the other hand, when the acceleration / deceleration state is the high acceleration / deceleration state of the second state, the proximity determination unit 351 determines that the proximity detection state is satisfied when the first condition is satisfied. That is, in the high acceleration / deceleration state, the second condition in which the indirect wave is not received is not a proximity detection condition.

According to such a configuration, proximity detection conditions for determining foreign matter adhesion are set according to the acceleration / deceleration state. Therefore, it is possible to more appropriately detect the adhesion of the foreign matter M to the object detection sensor 21.

The adhesion determination threshold TH is not limited to two types, the first adhesion determination threshold TH1 and the second adhesion determination threshold TH2. That is, the adhesion determination threshold value TH may be set to three or more types corresponding to each of the three or more stages of acceleration / deceleration.

The inequality sign in each determination process may have an equal sign or no equal sign. That is, for example, "exceeding the threshold value" and "above the threshold value" can be replaced with each other. Similarly, "less than the threshold" and "below the threshold" can be replaced with each other.

It goes without saying that the elements constituting the above-described embodiment are not necessarily essential except when it is clearly stated that they are essential and when they are clearly considered to be essential in principle. In addition, when numerical values such as the number, numerical value, quantity, and range of components are mentioned, unless it is clearly stated that they are indispensable, or when the number is clearly limited in principle, the specification is specified. The present invention is not limited to the number of. Similarly, except when the shape, direction, positional relationship, etc. of the constituent elements are mentioned, when it is clearly stated that it is particularly essential, or when it is limited to a specific shape, direction, positional relationship, etc. in principle. The present invention is not limited to the shape, direction, positional relationship, and the like.

Modifications are also not limited to the above examples. Also, a plurality of variants can be combined with each other. Further, all or part of the above embodiments and all or part of the modifications may be combined with each other.

Each of the above functional configurations and methods may be implemented by a dedicated computer provided by configuring a processor and memory programmed to perform one or more functions embodied by a computer program. .. Alternatively, each of the above functional configurations and methods may be implemented by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, each of the above functional configurations and methods comprises a combination of a processor and memory programmed to perform one or more functions and a processor composed of one or more hardware logic circuits. It may be realized by one or more dedicated computers.

Specifically, the driving support ECU 30 is not limited to a well-known microcomputer provided with a CPU or the like. That is, all or part of the driving support ECU 30 may be a digital circuit configured to realize the above-mentioned functions, for example, an ASIC or FPGA such as a gate array. ASIC is an abbreviation for Application Specific Integrated Circuit. FPGA is an abbreviation for Field Programmable Gate Array.

Further, the computer program may be stored in a computer-readable non-transitional substantive storage medium as an instruction executed by the computer. That is, the device or method according to the present invention can also be expressed as a computer program including a procedure for realizing each of the above functions or methods, or as a non-transitional substantive storage medium that stores the program.

10 Vehicle 21 Object detection sensor 30 Driving support ECU (adhesion detection device)
301 Vehicle information acquisition unit 302 Distance measurement information acquisition unit 303 Acceleration / deceleration state acquisition unit 304 Threshold setting unit 305 Adhesion judgment unit B Object M Foreign matter

Claims (8)

Foreign matter (M) to the object detection sensor (21) that detects the object existing around the vehicle (10) by transmitting the exploration wave and receiving the received wave including the reflected wave by the object (B) of the exploration wave. ) Is an adhesion detection device (30) configured to detect adhesion.
When the count value corresponding to the duration of the proximity detection state in which the proximity state in which the object detection sensor and the object are close to each other is detected exceeds the adhesion determination threshold value, the adhesion of the foreign matter to the object detection sensor is determined. Adhesion determination unit (305) and
The acceleration / deceleration state acquisition unit (303) that acquires the acceleration / deceleration state of the vehicle, and
A threshold setting unit (304) that sets the adhesion determination threshold value according to the acceleration / deceleration state acquired by the acceleration / deceleration state acquisition unit.
Adhesion detection device equipped with. The threshold setting unit is
In the first state in which the acceleration / deceleration state is different from the high acceleration / deceleration state, the adhesion determination threshold value is set to the first adhesion determination threshold value.
In the second state in which the acceleration / deceleration state is the high acceleration / deceleration state, the adhesion determination threshold value is set to a second adhesion determination threshold value whose corresponding duration is shorter than the first adhesion determination threshold value. ,
The adhesion detection device according to claim 1. The object detection sensor is a distance measuring sensor that detects a distance from the object.
The adhesion detection device according to claim 1 or 2. The object detection sensor is provided in a driving support system (20) that executes driving support in the vehicle.
The adhesion detection device according to any one of claims 1 to 3. Foreign matter (M) to the object detection sensor (21) that detects the object existing around the vehicle (10) by transmitting the exploration wave and receiving the received wave including the reflected wave by the object (B) of the exploration wave. ) Adhesion detection method, which detects adhesion
Acquire the acceleration / deceleration state of the vehicle,
An adhesion determination threshold is set according to the acquired acceleration / deceleration state, and
When the count value corresponding to the duration of the proximity detection state in which the proximity state in which the object detection sensor and the object are close to each other is detected exceeds the adhesion determination threshold value, the foreign matter adheres to the object detection sensor. judge,
Adhesion detection method. In the first state in which the acceleration / deceleration state is different from the high acceleration / deceleration state, the adhesion determination threshold value is set to the first adhesion determination threshold value.
In the second state in which the acceleration / deceleration state is the high acceleration / deceleration state, the adhesion determination threshold value is set to a second adhesion determination threshold value whose corresponding duration is shorter than the first adhesion determination threshold value. ,
The adhesion detection method according to claim 5. The object detection sensor is a distance measuring sensor that detects a distance from the object.
The adhesion detection method according to claim 5 or 6. The object detection sensor is used for driving support in the vehicle.
The adhesion detection method according to any one of claims 5 to 7.

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