WO2017060975A1 - 駐車形態判定装置 - Google Patents
駐車形態判定装置 Download PDFInfo
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- WO2017060975A1 WO2017060975A1 PCT/JP2015/078329 JP2015078329W WO2017060975A1 WO 2017060975 A1 WO2017060975 A1 WO 2017060975A1 JP 2015078329 W JP2015078329 W JP 2015078329W WO 2017060975 A1 WO2017060975 A1 WO 2017060975A1
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- parking
- distance
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- vehicle
- reflection
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Classifications
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Definitions
- the present invention relates to a parking pattern determination device that determines a parking pattern using distance information measured by a distance sensor mounted on a vehicle.
- a parking assistance device that supports driving of a vehicle up to a parking space
- the driver determines whether the parking space is a parallel parking configuration or a parallel parking configuration based on the surrounding parked vehicle, and the parking assistance device.
- the parking assistance device was instructing. For this reason, there are problems such as complicated operations performed by the driver and problems that the vehicle is erroneously guided when the driver misoperates.
- the parking assist device described in Patent Document 1 determines an appropriate parking direction based on the direction of each obstacle present on both sides of the target parking position. This obstacle is often a car.
- the parking assist device determines a target parking position for parking, detects an obstacle existing around the target parking position using a distance sensor such as an ultrasonic sensor, and on both sides of the target parking position based on the detection result.
- the direction of each obstacle present is estimated, and the target parking direction that is the direction of the vehicle at the target parking position is determined.
- the parking assist device described in Patent Document 1 estimates the end point of each obstacle on the target parking position side, and based on the direction of the straight line connecting the end points, The target parking direction was determined.
- the determination of the parking form is not performed, there is a possibility that the parallel parking form may be erroneously determined when there are two or three or more vacant spaces in the parallel parking form parking area. was there.
- Patent Document 1 discloses another method.
- the front part of the vehicle can be approximated by a straight line
- the side part of the vehicle can be approximated by a straight line or a quadratic curve having a small curvature.
- the direction orthogonal to the approximate straight line corresponds to the longitudinal axis of the vehicle, that is, the target parking direction.
- the direction of the approximate straight line corresponds to the target parking direction.
- the present invention has been made to solve the above-described problems, and an object thereof is to automatically determine whether the parking mode is parallel parking, parallel parking, or diagonal parking.
- a parking pattern determination device uses a transmission / reception result of a transmission wave by a distance sensor to measure a distance to an obstacle on the side of the own vehicle, and to measure the position of the own vehicle A position measurement unit, a reflection position calculation unit that calculates a reflection position of a transmission wave using the distance measured by the distance measurement unit and the own vehicle position measured by the own vehicle position measurement unit, and a plurality of calculations performed by the reflection position calculation unit And a grouping unit that divides the reflection position of each of the obstacles into groups, and an inclination line of the approximate line by obtaining an approximation line for each of two or more adjacent reflection positions among a plurality of reflection positions divided into the same group Or, based on the angle calculation unit that calculates the inclination angle of the normal and the distribution of the plurality of inclination angles calculated from the plurality of reflection positions divided into the same group, the parking mode is parallel parking, parallel parking or diagonal parking Which is In which and a determining the parking mode determining section.
- an approximate line is obtained for each of two or more adjacent reflection positions among a plurality of reflection positions divided into the same group, and an inclination angle of the approximate line or a normal line is calculated. Since it is determined whether the parking mode is parallel parking, parallel parking or diagonal parking based on the distribution of the inclination angle, it is automatically determined whether the parking mode is parallel parking, parallel parking or diagonal parking. Can be determined.
- FIG. 6 is a diagram illustrating an example of a reflection position data group obtained by grouping reflection position data by the grouping unit according to Embodiment 1.
- FIG. 6 is a diagram illustrating a method of calculating an inclination angle of an approximate line by the angle calculation unit according to Embodiment 1.
- FIG. 6 is a diagram illustrating a method of calculating an inclination angle of a normal line of an approximate line by the angle calculation unit according to Embodiment 1.
- FIG. 5 is a flowchart showing an example of the operation of the parking pattern determination device according to the first embodiment. It is a block diagram which shows the structural example of the parking form determination apparatus which concerns on Embodiment 2 of this invention.
- 6 is a diagram illustrating an example of reflection position data subjected to data processing by a data processing unit according to Embodiment 2.
- FIG. It is a figure which shows the deletion method of the reflective position data obtained by the data processing part of Embodiment 2 by the 2-circle intersection process.
- FIG. 1 is a diagram illustrating an outline of a parking mode determination method according to the present invention.
- a vehicle 10 is a vehicle equipped with a parking form determination device according to the present invention.
- the vehicle 10 is equipped with distance sensors 11 and 12 on the left and right sides in front.
- the distance sensors 11, 12 are transmitted from the vehicle 10 to the side when the vehicle 10 is traveling in the traveling direction A in the vicinity of the parked vehicle such as the parallel parked vehicle 21, the parallel parked vehicle 22, and the diagonally parked vehicle 23.
- a wave is transmitted, and a transmission wave reflected by a parked vehicle that is an obstacle is received as a reflected wave.
- the parking pattern determination device calculates each reflection position as indicated by, for example, a circle using the transmission / reception results of the distance sensors 11 and 12, and determines the parking pattern of the parked vehicle using these reflection positions.
- the distance sensor used by the parking pattern determination device may be any sensor that senses the left and right sides of the vehicle 10.
- FIG. 1 shows an example using two distance sensors 11 and 12 installed on the front side of the vehicle 10
- two distance sensors installed on the rear side may be used, or installed on the front side and rear side.
- Four distance sensors may be used.
- the distance sensors 11 and 12 may be any sensors that can measure the distance from the vehicle 10 to the obstacle by transmitting and receiving transmission waves.
- an ultrasonic sensor that transmits and receives ultrasonic waves as transmission waves
- a radar that transmits and receives radio waves, and the like. It is.
- FIG. 2 is a block diagram illustrating a configuration example of the parking pattern determination device 1 according to the first embodiment of the present invention.
- the parking form determination device 1 includes a distance measurement unit 2, a host vehicle position measurement unit 3, a reflection position calculation unit 4, a grouping unit 5, an angle calculation unit 6, and a parking form determination unit 7.
- the parking mode determination device 1 includes left and right distance sensors 11 and 12, left and right wheel speed sensors 13 and 14, a yaw rate sensor 15, a GPS (Global Positioning System) sensor 16, an input device 17, and an output mounted on the vehicle 10.
- the device 18 and the parking assist device 19 are electrically connected.
- the distance sensors 11 and 12 output the transmission / reception result of the transmission wave transmitted toward the side of the vehicle 10 to the distance measurement unit 2.
- the wheel speed sensors 13 and 14 detect the left and right wheel speeds of the vehicle 10 and output them to the vehicle position measuring unit 3.
- the yaw rate sensor 15 detects the yaw rate of the vehicle 10 and outputs it to the vehicle position measuring unit 3.
- the GPS sensor 16 receives radio waves from GPS satellites and outputs them to the vehicle position measuring unit 3.
- the input device 17 is, for example, a touch panel disposed on the display, or a button provided on the housing of the parking form determination device 1.
- the input device 17 receives a driver's operation on a button or the like, and outputs a signal indicating the operation content to the parking pattern determination device 1.
- the input device 17 receives a signal from the driver that parking mode determination is started and outputs the signal to the distance measuring unit 2 and the vehicle position measuring unit 3.
- the input device 17 is a lighting switch for the hazard lamp of the vehicle 10, and when the lighting switch is turned on, a signal for instructing the parking mode determination start is used as a signal for starting the parking mode determination, and the distance measuring unit 2 and The structure which outputs to the own vehicle position measurement part 3 may be sufficient.
- the input device 17 is a shift lever of the vehicle 10, and when the shift lever is operated to the parking range, a signal for instructing the start of the parking form determination is sent to the distance measuring unit 2 and the signal indicating the start of the parking form determination.
- the structure which outputs to the own vehicle position measurement part 3 may be sufficient.
- the output device 18 is, for example, a display or a speaker.
- the output device 18 receives information to be displayed from the parking pattern determination device 1 and displays it on the display.
- the output device 18 receives information to be output from the parking form determination device 1 and outputs the information from the speaker.
- the output device 18 displays the determination result of the parking pattern received from the parking pattern determination unit 7 on the display or outputs it from the speaker.
- the parking support device 19 receives the determination result of the parking mode from the output device 18, and supports the parking operation of the vehicle 10 according to the parking mode. Since a technique for supporting the operation of the vehicle 10 when parking is performed using a known technique, the description thereof is omitted.
- the parking assistance apparatus 19 may perform the automatic parking of the vehicle 10 by unmanned driving
- FIG. 3 is a diagram illustrating a hardware configuration example of the parking pattern determination device 1.
- the parking form determination apparatus 1 is configured by, for example, an ECU (Electronic Control Unit) 30.
- the ECU 30 includes a transmission / reception circuit 31, a memory 33, and a processor 32 that executes a program stored in the memory 33.
- the transmission / reception circuit 31 is a circuit that transmits transmission waves from the distance sensors 11 and 12 and receives reflected waves received by the distance sensors 11 and 12.
- the functions of the distance measurement unit 2, the vehicle position measurement unit 3, the reflection position calculation unit 4, the grouping unit 5, the angle calculation unit 6, and the parking mode determination unit 7 in the parking mode determination device 1 are software, firmware, or software. This is realized by a combination of firmware and firmware.
- Software or firmware is described as a program and stored in the memory 33.
- the processor 32 implements the functions of the respective units by reading out and executing the program stored in the memory 33. That is, when executed by the processor 32, the parking mode determination device 1 measures the distance to the obstacle, the step of measuring the position of the own vehicle, the transmission wave in the obstacle using the distance and the own vehicle position.
- a step of calculating the reflection position a step of dividing the plurality of reflection positions into groups for each obstacle, and obtaining an approximate line of two or more adjacent reflection positions among the plurality of reflection positions divided into the same group
- the memory 33 is provided.
- this program causes the computer to execute the procedures or methods of the distance measuring unit 2, the vehicle position measuring unit 3, the reflection position calculating unit 4, the grouping unit 5, the angle calculating unit 6, and the parking form determining unit 7. It can be said that there is.
- the processor 32 is, for example, a CPU (Central Processing Unit), a central processing unit, a processing unit, an arithmetic unit, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor).
- the memory 33 is, for example, a nonvolatile or volatile semiconductor memory such as a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, an EPROM (Erasable Programmable ROM), or an EEPROM (Electrically EPROM).
- the distance measuring unit 2 receives information on the time taken from transmission to reception of the transmission wave as a transmission / reception result of the transmission wave from the distance sensor 11. Then, the distance measurement unit 2 measures the distance to the obstacle on the side of the vehicle 10 using the transmission / reception result, and outputs the distance data to the reflection position calculation unit 4. The distance measuring unit 2 also measures the distance for the distance sensor 12 in the same manner as described above, and outputs the distance data to the reflection position calculating unit 4. Since the distance sensors 11 and 12 are often mounted on the vehicle 10, existing products can be used. Or the structure provided with the distance sensors 11 and 12 may be sufficient as the parking form determination apparatus 1. FIG.
- the own vehicle position measurement unit 3 receives the reception result of the radio wave from the GPS sensor 16, measures the own vehicle position, and outputs the own vehicle position data to the reflection position calculation unit 4. Since the GPS sensor 16 is often mounted on the vehicle 10, existing products can be used. In addition, since the absolute position can be measured by positioning using the GPS sensor 16, it is effective for use in automatic parking by unmanned traveling.
- the measurement of the vehicle position is not limited to the above method using the GPS sensor 16.
- the own vehicle position measuring unit 3 receives the wheel speed of the vehicle 10 from the wheel speed sensors 13 and 14 and converts it to a traveling speed.
- the host vehicle position measurement unit 3 receives the yaw rate of the vehicle 10 from the yaw rate sensor 15. Then, the host vehicle position measurement unit 3 calculates the travel direction change amount ⁇ i per unit time from the yaw rate, and calculates the movement distance ⁇ D i per unit time from the traveling speed.
- the own vehicle position measurement unit 3 uses the following expressions (1), (2), and (3) together with the known own vehicle position (x i ⁇ 1 , y i ⁇ 1 ) and the direction ⁇ i ⁇ 1.
- the current vehicle position (x i , y i ) and direction ⁇ i are calculated.
- ⁇ i ⁇ i ⁇ 1 + ⁇ i (1)
- x i x i ⁇ 1 + ⁇ D i sin ⁇ i (2)
- y i y i ⁇ 1 + ⁇ D i cos ⁇ i (3)
- the wheel speed sensors 13 and 14 and the yaw rate sensor 15 are often mounted on the vehicle 10, existing products can be used. Also, with this method, the vehicle position can be measured even when the vehicle 10 is traveling in a place where GPS satellite radio waves do not reach.
- the own vehicle position measuring unit 3 may measure the own vehicle position using the GPS sensor 16, may measure the own vehicle position using the wheel speed sensors 13, 14 and the yaw rate sensor 15, or The vehicle position may be measured using the sensor 16, the wheel speed sensors 13 and 14, and the yaw rate sensor 15.
- the vehicle position measurement method described below is applied to Embodiment 3 to be described later, the vehicle position can be measured more accurately, so that measurement errors in parking spaces and obstacle sizes are suppressed. it can. Therefore, the accuracy of parking form determination increases.
- FIG. 22 shows a configuration example of the vehicle position measurement unit 3.
- D1 D ⁇ ⁇ 1.
- the standard deviation ⁇ 1 is defined by the radio wave reception status and the signal-to-noise ratio of the received signal.
- the distance D1 measured by the GPS sensor 16 and the wheel speed sensor 13 are different.
- 14 has a difference in the distance D2.
- the distance D actually traveled, the distance D2 measured by the wheel speed sensors 13 and 14, the actual wheel diameter R, and the wheel diameter management value R ′ have the following expressions (4) and (5).
- R / R ′ D / D2 (4)
- R R ′ ⁇ D / D2 (5)
- the vehicle position measurement unit 3 cannot measure the actual traveled distance D, and therefore uses the distance D1 measured by the GPS sensor 16 instead. That is, the above expressions (4) and (5) can be expressed as the following expressions (4a) and (5a).
- R / R ′ D1 / D2 (4a)
- R R ′ ⁇ D1 / D2 (5a)
- the first distance measuring unit 3-1 shown in FIG. 22 measures the distance D1 traveled by the vehicle 10 using the GPS sensor 16 in which the measurement error becomes a sequential error.
- the second distance measuring unit 3-2 measures the distance D2 traveled by the vehicle 10 using the wheel speed sensors 13 and 14 in which the measurement error is an accumulated error.
- the correction value calculation unit 3-3 uses the distance D1 measured by the first distance measurement unit 3-1 and the distance D2 measured by the second distance measurement unit 3-2, for example, periodically using the above formula.
- the wheel diameter R is calculated from (4a) and (5a).
- the own vehicle position measuring unit 3 replaces the wheel diameter management value R ′ with the wheel diameter R calculated by the correction value calculating unit 3-3, and measures the own vehicle position using the wheel speed sensors 13 and 14 and the yaw rate sensor 15. I do.
- the wheel diameter R is a correction value for measuring the vehicle position.
- the error between the wheel diameter R and the wheel diameter management value R ′ can be corrected, and the vehicle position can be measured more accurately.
- the vehicle position measurement unit 3 can reduce the influence of the standard deviation ⁇ 1 of the distance D1 measured by the GPS sensor 16 by calculating the wheel diameter R at a plurality of points.
- the reflection position calculation unit 4 receives distance data from the distance measurement unit 2 and receives host vehicle position data from the host vehicle position measurement unit 3.
- the own vehicle position measuring unit 3 uses the own vehicle position data when the distance sensor 11 or the distance sensor 12 measures the distance, that is, when the transmission wave is transmitted / received, and is a sensor that is the position of the distance sensor 11 or the distance sensor 12 Calculate the position.
- the own vehicle position measuring unit 3 links the calculated sensor position data and the distance data measured at the sensor position to form a set of data. Note that information on the installation positions of the distance sensors 11 and 12 in the vehicle 10 necessary for calculating the sensor position is set in the reflection position calculation unit 4 in advance.
- the reflection position calculation unit 4 calculates one reflection position by using a set of sensor position data and distance data and a direction in which the directivity of the distance sensors 11 and 12 is maximized.
- the reflection position calculation unit 4 outputs the calculated reflection position data to the grouping unit 5.
- a direction in which the directivity of the distance sensors 11 and 12 is maximized is referred to as a “maximum directivity direction”. Information on the maximum directivity direction is set in the reflection position calculation unit 4 in advance.
- FIG. 4 is a diagram for explaining a method of calculating the reflection position using the maximum directivity direction of the distance sensor 11.
- FIG. 4 shows sensor position data a1 to a13 and distance data b1 to b13 obtained when the vehicle 10 travels in the traveling direction A. Further, the maximum directivity direction B in the sensor position data a1 to a13 of the distance sensor 11 is indicated by a broken line.
- the reflection position calculation unit 4 calculates a position away from the sensor position data a1 by the distance data b1 in the maximum directivity direction B, and sets this position as reflection position data c1. Similarly, the reflection position calculation unit 4 calculates the reflection positions c2 to c13 in the maximum directivity direction B using the sensor position data a2 to a13 and the distance data b2 to b13.
- FIG. 5 is a diagram illustrating a method of calculating the reflection position using a known technique called two-circle intersection processing as a method different from the method described in FIG.
- FIG. 5 shows sensor position data a1 and distance data b1, and sensor position data a2 and distance data b2 obtained when the vehicle 10 travels in the traveling direction A.
- the maximum directivity direction B in the sensor position data a1 and a2 of the distance sensor 11 is indicated by a broken line.
- the reflection position calculation unit 4 obtains a circle having the sensor position data a1 as the center and the distance data b1 as the radius.
- the reflection position calculation unit 4 obtains a circle having the sensor position data a2 as the center and the distance data b2 as the radius. Then, the reflection position calculation unit 4 calculates the obtained intersection position of the two circles and sets this intersection position as reflection position data c1.
- the grouping unit 5 receives the reflection position data from the reflection position calculation unit 4, divides it into groups for each obstacle, and outputs them to the angle calculation unit 6. Specifically, when the distance between the reflection position data adjacent to each other is equal to or less than a predetermined threshold, the grouping unit 5 determines that each of the adjacent reflection position data is data included in the same group, and is adjacent. When the distance between the reflection position data is larger than a predetermined threshold, the adjacent reflection position data is determined as data belonging to different groups.
- the grouping unit 5 extracts adjacent reflection position data with reference to the positions indicated by the sensor position data of the distance sensors 11 and 12. In this case, reflection position data c6 and c7 corresponding to adjacent sensor position data a6 and a7 in FIG. 4 are extracted, and it is determined whether or not the distance between the reflection position data c6 and c7 is equal to or less than a threshold value. Alternatively, the grouping unit 5 may extract adjacent reflection position data based on the shortest distance of the reflection position data. In this case, for the reflection position data c6 in FIG. 4, the reflection position data c7 having the shortest distance relationship with the reflection position data c6 is selected, and these reflection position data c6 and c7 are adjacent to each other as reflection position data. Extracted.
- the threshold used by the grouping unit 5 for grouping is a value for distinguishing an obstacle such as a parked vehicle from a parking space.
- the grouping unit 5 may change the threshold used for grouping according to the traveling speed of the vehicle 10 or the sensing frequency of the distance sensors 11 and 12.
- the grouping unit 5 uses a large threshold when the traveling speed is high or the sensing frequency is low, and uses a small threshold when the traveling speed is low or the sensing frequency is high. It is assumed that the correspondence relationship between the traveling speed or the sensing frequency and the threshold is set in the grouping unit 5 in advance.
- FIG. 6 is a diagram illustrating an example of a reflection position data group obtained by grouping reflection position data.
- a plurality of reflection position data obtained when the vehicle 10 travels in the traveling direction A is grouped into four reflection position data groups G1 to G4.
- the parking form determination apparatus 1 since there is no obstacle between reflection position data groups, it is regarded as a parking space.
- the angle calculation unit 6 receives the grouped reflection position data from the grouping unit 5. Then, the angle calculation unit 6 obtains an approximate line of two or more adjacent reflection position data among a plurality of reflection position data included in the same group, and calculates the inclination angle of the approximation line or the inclination of the normal line. Calculate the angle. The angle calculation unit 6 calculates an inclination angle for all the reflection position data included in the same group, and outputs it to the parking pattern determination unit 7. The angle calculation unit 6 may extract adjacent reflection position data with reference to the position indicated by the sensor position data, or may extract with reference to the shortest distance of the reflection position data.
- FIG. 7 is a diagram illustrating a method of calculating the inclination angle of the approximate line.
- FIG. 7 shows the reflection position data c1 to c13 of the same group obtained when the vehicle 10 travels in the traveling direction A.
- the angle calculation unit 6 calculates approximate lines of the three reflection position data c1 to c3, and calculates the inclination angle ⁇ d1 of the approximate lines.
- the angle calculation unit 6 calculates the inclination angle ⁇ d1 of the approximate line with the maximum directivity direction B as the reference axis, but the reference axis is not limited to the maximum directivity direction B.
- the traveling direction A may be used.
- the angle calculation unit 6 obtains an approximate line of the two reflection position data c4 and c5, and calculates the inclination angle ⁇ d2 of the approximate line.
- the angle calculation unit 6 repeats the above processing, and calculates the tilt angle so that all of the reflection position data c1 to c13 are used for any calculation.
- FIG. 8 is a diagram illustrating a method of calculating the inclination angle of the normal line of the approximate line.
- FIG. 8 shows reflection position data c1 to c13 of the same group obtained when the vehicle 10 travels in the traveling direction A.
- the angle calculation unit 6 obtains approximate lines of the three reflection position data c1 to c3, and calculates the inclination angle ⁇ d1 of the normal line of the approximate lines.
- the angle calculation unit 6 calculates the normal inclination angle ⁇ d1 with the maximum directivity direction B as the reference axis, but the reference axis is not limited to the maximum directivity direction B.
- the traveling direction A may be used.
- the angle calculation unit 6 obtains an approximate line of the two reflection position data c4 and c5, and calculates the inclination angle ⁇ d2 of the approximate line.
- the angle calculation unit 6 repeats the above processing, and calculates the tilt angle so that all of the reflection position data c1 to c13 are used for any calculation.
- the parking form determination unit 7 receives a plurality of inclination angles calculated from a plurality of reflection position data included in the same group from the angle calculation unit 6. And the parking pattern determination part 7 determines whether the parking pattern of the group is parallel parking, parallel parking, or diagonal parking based on the distribution of all inclination angles included in the same group, and determination The result is output to the output device 18 or the parking assist device 19.
- FIG. 9 shows an example of parallel parking
- FIG. 10 shows an example of parallel parking
- FIG. 11 shows an example of diagonal parking.
- the distance data is displayed on a two-dimensional plane in the front-rear direction and the left-right direction of the vehicle 10.
- the reflection position data along the contour line of the parallel parked vehicle 21 as indicated by a circle is obtained.
- the angle calculation unit 6 obtains approximate lines of adjacent reflection position data, and calculates the inclination angles ⁇ d1 to ⁇ d13 of the normal lines of the approximate lines by the following equation (6).
- the parking form determination unit 7 creates a histogram as shown in FIG. 9C using the inclination angles ⁇ d1 to ⁇ d13.
- ⁇ dm is the inclination angle of the normal line of the approximate line
- m 1 to 13.
- ⁇ dm is the inclination angle of the normal line of the approximate line
- m 1 to 13.
- the distance sensor 11 of the vehicle 10 transmits / receives a transmission wave to / from the parallel parked vehicle 22, it follows the contour line of the parallel parked vehicle 22 as indicated by a circle. Reflection position data is obtained.
- the angle calculation unit 6 obtains approximate lines of adjacent reflection position data, and calculates inclination angles ⁇ d1 to ⁇ d10 of normal lines of the approximate lines.
- the parking form determination unit 7 creates a histogram as shown in FIG. 10C using the inclination angles ⁇ d1 to ⁇ d10.
- the distance sensor 11 of the vehicle 10 transmits / receives a transmission wave to / from the obliquely parked vehicle 23, it follows the outline of the obliquely parked vehicle 23 as indicated by a circle. Reflection position data is obtained. As shown in FIG. 11B, the angle calculation unit 6 obtains approximate lines of adjacent reflection position data, and calculates inclination angles ⁇ d1 to ⁇ d7 of normal lines of the approximate lines. The parking form determination unit 7 creates a histogram as shown in FIG. 11C using the inclination angles ⁇ d1 to ⁇ d7.
- the parking form determination unit 7 creates a histogram of the class width and the number of classes determined in advance.
- the parking form determination unit 7 creates a histogram by dividing the range of ⁇ 90 degrees into five classes with equal class widths. Yes.
- a class including an inclination angle from ⁇ 18 degrees to 18 degrees is called a 0-degree class.
- FIG. 9C when the inclination angle distribution is concentrated in the 0 degree class, that is, when the distribution width is narrow, parallel parking is performed.
- FIG. 10C when the distribution of inclination angles is widely dispersed from the vicinity of the 0 degree class, that is, when the distribution width is wide, parallel parking is performed.
- FIG. 11 (c) when the distribution of the inclination angles is distributed in a positive or negative class, the parking is oblique.
- a first method for determining the parking mode based on the distribution characteristics as described above there is a method using an average value and a variance value of a plurality of inclination angles in the same group.
- This threshold value is a value for determining whether the distribution width of the tilt angle is narrow or wide.
- the parking form determination unit 7 creates a histogram using a plurality of inclination angles of the same group.
- the parking form determination part 7 calculates the average value and dispersion value of this group using the class value and frequency of each class.
- the parking form determination part 7 may calculate an average value and a dispersion
- a second method for determining the parking mode there is a method using a class that becomes the mode L of the histogram and a ratio L / M of the mode L to the total number M of inclination angles.
- the parking form determination unit 7 uses the second method, it is assumed that the table shown in FIG.
- the ratio L / M is a large value when the distribution width is narrow, and a small value when the distribution width is wide.
- the parking form determination unit 7 creates a histogram using a plurality of inclination angles of the same group. And the parking form determination part 7 will determine with parallel parking if the class used as the mode L is 0 degree
- the parking form determination part 7 will determine with parallel parking, if the class used as the mode L is 0 degree
- a third method for determining the parking mode there is a method using the class that becomes the mode L of the histogram and the ratio O / L of the frequency O of the class having the second highest frequency to the mode L. is there.
- the parking form determination unit 7 uses the third method, it is assumed that the table shown in FIG.
- the ratio O / L is a small value when the distribution width is narrow, and a large value when the distribution width is wide.
- the parking form determination unit 7 creates a histogram using a plurality of inclination angles of the same group. And the parking form determination part 7 will determine with parallel parking, if the class used as the mode L is 0 degree
- the parking form determination part 7 will determine with parallel parking, if the class used as the mode L is 0 degree
- the parking pattern determination unit 7 may evaluate the reliability of the determination result of the parking pattern according to the number of reflection position data divided into the same group. For example, if the number of reflection position data divided into the same group is equal to or greater than a predetermined threshold, the parking pattern determination unit 7 evaluates that the determination result of the group is highly reliable, and conversely, the number of reflection position data Is less than a predetermined threshold value, it is evaluated that the determination result of the group is low in reliability.
- the parking form determination unit 7 may evaluate the reliability at a plurality of levels using a plurality of thresholds. Moreover, when the parking form determination unit 7 evaluates that the reliability of the determination result of the parking form is low, the parking form determination unit 7 may output the determination result to the output device 18 and inquire the driver about the correctness of the determination result.
- the parking pattern determination unit 7 not only determines the parking pattern of one parked vehicle using the determination result of the parking pattern of one group, but also uses the determination result of the parking pattern of a plurality of groups to park the parking area. You may determine the whole parking form. For example, the parking pattern determination unit 7 determines the determination result of the most parking pattern among the determination results of the parking patterns of a plurality of groups as the parking pattern of the entire parking area. Moreover, the parking form determination part 7 may exclude the determination result evaluated that reliability is low, and may determine the parking form of the whole parking area using the remaining determination results.
- FIG. 15 is a flowchart illustrating an example of the operation of the parking form determination device 1.
- the reflection position calculation unit 4 performs a two-circle intersection process
- the parking mode determination unit 7 determines the parking mode by the second method.
- step ST11 the parking form determination apparatus 1 proceeds to step ST12 when the start condition for parking form determination is satisfied (step ST11 “YES”), and when the start condition is not satisfied (step ST11 “NO”), step ST11 is performed. repeat.
- step ST12 the distance measurement unit 2 starts distance measurement using the distance sensors 11 and 12, and the own vehicle position measurement unit 3 detects the wheel speed sensors 13 and 14 and the yaw rate sensor 15 or the GPS. The vehicle position measurement using the sensor 16 is started. Then, the distance measurement unit 2 starts outputting distance data to the reflection position calculation unit 4, and the own vehicle position measurement unit 3 starts outputting own vehicle position data to the reflection position calculation unit 4.
- the parking condition determination start condition is, for example, when the traveling speed of the vehicle 10 is equal to or lower than a predetermined threshold (for example, 20 km / h).
- a predetermined threshold for example, 20 km / h.
- the own vehicle position measurement unit 3 receives the detection values from the wheel speed sensors 13 and 14 and calculates the travel speed, for example, and starts its own operation when the travel speed falls below the threshold value. Signal the start of operation.
- the parking condition determination start condition is when the driver gives a signal to start the parking pattern determination.
- a signal instructing the parking mode start is output from the input device 17 to the distance measuring unit 2 and the vehicle position measuring unit 3. .
- the distance measuring unit 2 and the vehicle position measuring unit 3 receive this signal, they start operating.
- step ST ⁇ b> 13 the reflection position calculation unit 4 performs a two-circle intersection process using the distance data received from the distance measurement unit 2 and the own vehicle position data received from the own vehicle position measurement unit 3 to calculate the reflection position data. And output to the grouping unit 5.
- step ST14 the grouping unit 5 receives the reflection position data from the reflection position calculation unit 4, and groups the reflection position data by determining whether the distance between the adjacent reflection position data is equal to or less than a threshold value. .
- the grouping unit 5 outputs the grouped reflection position data to the angle calculation unit 6.
- step ST15 the angle calculation unit 6 receives a plurality of reflection position data of the same group from the grouping unit 5.
- the angle calculation unit 6 calculates an inclination angle by obtaining an approximate line for each of two or more adjacent reflection position data in the same group.
- the angle calculation unit 6 calculates the tilt angle using all the reflection position data of the same group, and then outputs it to the parking pattern determination unit 7.
- step ST16 the parking pattern determination unit 7 receives a plurality of inclination angles of the same group from the angle calculation unit 6, and creates a histogram.
- step ST17 the parking pattern determination unit 7 determines whether the parking pattern of this group is parallel parking, parallel parking, or diagonal parking using the created histogram and the table shown in FIG.
- the parking form determination unit 7 outputs the determination result to the parking support device 19.
- the parking pattern determination device 1 uses the distance measurement unit 2 that measures the distance to the obstacle on the side of the host vehicle using the transmission / reception results of the transmission waves by the distance sensors 11 and 12; Reflection position calculation that calculates the reflection position of the transmission wave using the own vehicle position measurement unit 3 that measures the position of the own vehicle, and the distance measured by the distance measurement unit 2 and the own vehicle position measured by the own vehicle position measurement unit 3 Unit 4, grouping unit 5 that divides the plurality of reflection positions calculated by reflection position calculation unit 4 into groups for each obstacle, and two or more adjacent reflections among the plurality of reflection positions divided into the same group An angle calculation unit 6 that calculates an approximate line for each position and calculates an inclination angle of the approximate line or a normal line, and a distribution of a plurality of inclination angles calculated from a plurality of reflection positions divided into the same group. Based on the parking type parallel parking A configuration and a parking mode determining section 7 determines which of the parallel parking or diagonal parking. Thereby, it can be
- the structure provided with the distance sensors 11 and 12 which transmit / receive a transmission wave toward the side of the own vehicle may be sufficient as the parking form determination apparatus 1 which concerns on Embodiment 1.
- the distance sensors 11 and 12 may be either ultrasonic type or radar type. Since the ultrasonic distance sensor is less expensive than the radar type, the parking pattern determination device 1 can be realized at a lower cost. Since the radar type distance sensor has a longer radio wave reach than ultrasonic waves, it can determine the parking mode by detecting farther obstacles.
- the own vehicle position measuring unit 3 is configured to measure the own vehicle position using the GPS sensor 16. Thereby, the own vehicle position can be measured using the existing product mounted on the own vehicle. In addition, since the absolute position can be measured by positioning using the GPS sensor 16, it is effective for use in automatic parking by unmanned traveling.
- the own vehicle position measuring unit 3 is configured to measure the own vehicle position using the traveling speed detected by the wheel speed sensors 13 and 14 and the yaw rate detected by the yaw rate sensor 15. There may be. Thereby, the own vehicle position can be measured using the existing product mounted on the own vehicle. Even when the vehicle is traveling in a place where radio waves from GPS satellites do not reach, the vehicle position can be measured.
- the own vehicle position measuring unit 3 includes the first distance measuring unit 3-1 that measures the traveling distance of the own vehicle using the GPS sensor 16 in which the measurement error becomes a sequential error, A second distance measuring unit 3-2 that measures the traveling distance of the host vehicle using the wheel speed sensors 13 and 14 in which the measurement error is an accumulated error, and a traveling distance measured by the first distance measuring unit 3-1, It may be configured to include a correction value calculation unit 3-3 that calculates a correction value for measuring the vehicle position using the travel distance measured by the second distance measurement unit 3-2. Thereby, the own vehicle position can be measured more accurately.
- the distance measuring unit 2 and the own vehicle position measuring unit 3 are configured to operate when the own vehicle is traveling at a predetermined speed or less.
- the parking form determination apparatus 1 can start the determination of the parking form when the own vehicle enters the parking area. Further, since the driver does not need to perform an operation to instruct the parking mode determination device 1 to start the parking mode determination, the driver can concentrate on driving.
- the distance measuring unit 2 and the vehicle position measuring unit 3 may be configured to operate when a signal instructing the start of parking mode determination is received. Thereby, the parking form determination apparatus 1 can start the determination of a parking form, when the vehicle 10 parks.
- the reflection position calculation unit 4 includes the distance measured by the distance measurement unit 2, the positions of the distance sensors 11 and 12 at the time of distance measurement calculated using the vehicle position, and the distance sensor.
- one reflection position is calculated using the direction in which the directivity of 11 and 12 is maximized.
- the reflection position can be calculated in a shorter time than the two-circle intersection process.
- the reflection position calculation unit 4 includes two sets of the distance measured by the distance measurement unit 2 and the positions of the distance sensors 11 and 12 at the time of distance measurement calculated using the vehicle position.
- a configuration may be used in which two-circle intersection processing is performed to calculate one reflection position.
- the grouping unit 5 is configured to determine the adjacent reflection positions as the same group when the distance between the adjacent reflection positions is equal to or less than a predetermined threshold. This makes it easy to group reflection positions.
- the parking form determination part 7 calculates the average value and dispersion
- the parking pattern determination unit 7 creates a histogram of a plurality of inclination angles in the same group, the ratio between the total number of inclination angles and the mode value, and the maximum value.
- the structure which determines a parking form using the class used as a frequent value may be sufficient.
- the parking mode can be quantified and standardized, and a determination method independent of the shape of the parked vehicle can be realized.
- the parking form determination unit 7 creates a histogram of a plurality of inclination angles of the same group, and the mode value and the frequency of the second most frequent class
- the configuration may be such that the parking mode is determined using the ratio and the class that is the mode.
- the parking mode can be quantified and standardized, and a determination method independent of the shape of the parked vehicle can be realized.
- the parking pattern determination unit 7 evaluates that the reliability of the determination result of the parking pattern is high when the number of reflection positions divided into the same group is large, and the number of reflection positions is small. It is the structure which evaluates that the reliability of the determination result of a parking form is low. Thereby, when the reliability of the determination result is low, it is possible to take measures such as not using the parking support or inquiring the driver.
- the parking form determination part 7 is a structure which determines a parking form using the determination result of the parking form of a some group. Thereby, the reliability of a determination result can be improved. Moreover, the parking form of the whole parking area can be determined.
- FIG. FIG. 16 is a block diagram illustrating a configuration example of the parking pattern determination device 1 according to the second embodiment.
- the parking form determination apparatus 1 according to Embodiment 2 has a configuration in which a data processing unit 8 is added to the parking form determination apparatus 1 of Embodiment 1 illustrated in FIG.
- parts that are the same as or correspond to those in FIGS. 1 to 15 are given the same reference numerals, and descriptions thereof are omitted.
- the data processing unit 8 receives the reflection position data from the reflection position calculation unit 4 and performs data processing such as deletion of unnecessary reflection position data, interpolation of missing reflection position data, or correction of numerical values of the reflection position data.
- the subsequent reflection position data is output to the grouping unit 5.
- the data processing unit 8 is realized by the processor 32 shown in FIG. 3 executing a program stored in the memory 33.
- the data processing unit 8 obtains approximate curves for all the reflection position data c1 to c13 in FIG. 4, and deletes the reflection position data at a position away from the approximate curve by a predetermined threshold or more.
- the reflection position data c5 is deleted by the threshold determination.
- the data processing unit 8 may interpolate the reflection position data using the approximate curve with respect to the sensor position data from which the distance data is missing.
- the transmission wave is transmitted from the distance sensor 11, but the reflected wave cannot be received and the distance data is missing.
- the data processing unit 8 sets the distance at which the straight line extending from the sensor position data a8 in the maximum directivity direction B intersects the approximate curve as distance data b8, and sets the intersecting position as reflection position data c8.
- the data processing unit 8 interpolates the distance data b11 and the reflection position data c11 with respect to the sensor position data a11. Further, the data processing unit 8 may newly interpolate the distance data b5 and the reflection position data c5 by the above interpolation instead of the reflection position data c5 deleted by the threshold determination.
- the data processing unit 8 may correct the reflection position data that does not match the approximate curve so as to match the approximate curve.
- FIG. 17 shows an example after the reflection position data shown in FIG. 4 is deleted, interpolated, and corrected. Since the reflection position data c5 shown in FIG. 4 is at a position away from the approximate curve by a predetermined threshold or more, it is deleted, and new reflection position data c5 is interpolated in FIG. Since the sensor position data a8 and a11 shown in FIG. 4 lacks distance data and reflection position data, new reflection position data c8 and c11 are interpolated in FIG. Since the reflection position data c1, c2, c7, c9, c11, c12, and c13 shown in FIG. 4 do not match the approximate curve, they are corrected to match the approximate curve in FIG.
- the data processing unit 8 may delete unnecessary reflection position data from the reflection position data obtained by the two-circle intersection process. For example, the data processing unit 8 determines that the reflection position data c1 is valid if the reflection position data c1 is within the sensor viewing angle of the distance sensor 11 in the sensor position data a1 and a2, and outputs it to the grouping unit 5. Otherwise, it is determined to be invalid and deleted. Information on the sensor viewing angle is set in the data processing unit 8 in advance. Specifically, the data processing unit 8 determines that the reflection position data c1 is valid when the angles ⁇ e1 and ⁇ e2 with respect to the maximum directivity direction B of the reflection position data c1 in FIG. 18 are within the sensor viewing angle ⁇ e.
- the data processing unit 8 is configured to perform data processing on the reflection position data before being grouped. However, data processing is performed on the reflection position data after being grouped. You may make it the structure which performs.
- the data processing unit 8 performs at least one timing among steps ST12 and ST13, between steps ST13 and ST14, or between steps ST14 and ST15 in the series of processes shown in the flowchart of FIG. Then, the data processing described above is performed.
- the parking pattern determination device 1 deletes the reflection position deviated from the sensor viewing angle of the distance sensors 11 and 12 at the time of distance measurement from the reflection positions calculated by the two-circle intersection process.
- the data processing unit 8 is provided. By deleting unnecessary reflection position data, the accuracy of tilt angle calculation and parking mode determination is improved.
- FIG. 19 is a block diagram illustrating a configuration example of the parking pattern determination device 1 according to the third embodiment.
- the parking pattern determination device 1 according to the third embodiment has a configuration in which a size determination unit 9 is added to the parking pattern determination device 1 according to the first embodiment illustrated in FIG. 19, parts that are the same as or correspond to those in FIGS. 1 to 18 are given the same reference numerals, and descriptions thereof are omitted.
- the size determination unit 9 receives a plurality of reflection position data divided into the same group from the grouping unit 5, calculates a distance between the most distant reflection position data among the plurality of reflection position data, Determine the size of the obstacle. Then, the size determination unit 9 outputs the determined size to the parking form determination unit 7.
- the size determination unit 9 is realized by the processor 32 shown in FIG. 3 executing a program stored in the memory 33.
- the parking form determination unit 7 compares the size of the obstacle received from the size determination unit 9 with a predetermined threshold value to determine the type of the obstacle.
- the types of obstacles are, for example, vehicles, walls, small objects, and the like.
- the small object referred to here is an obstacle having a size smaller than that of the vehicle and the wall, for example, a pole.
- the threshold value is a value by which an obstacle can be determined based on its size, and is set in advance in the parking form determination unit 7. Since vehicles vary in size according to the types of ordinary cars, buses, trucks, etc., for example, a threshold range is defined in which the entire width of a light car is a lower limit (for example, 1 m) and the entire length of the truck is an upper limit (for example, 5 m). If the size of the obstacle is within the threshold range, it is determined that the vehicle is a small object.
- the example which performs parking form determination using distribution of the inclination angle contained in the same group, and the size of the obstacle of the group is demonstrated.
- the parking form determination unit 7 determines the parking form using the second method described in the first embodiment, the table shown in FIG. To do.
- the parking form determination unit 7 creates a histogram using a plurality of inclination angles of the same group.
- the parking form determination part 7 is the upper limit value (for example, 5m) when the class used as the mode L is 0 degree
- the parking form determination part 7 is parallel parking if the class used as the mode L is 0 degree
- the parking mode determination unit 7 determines that the vehicle is a diagonally parked vehicle if the class that is the mode L is other than 0 degrees and the ratio L / M is equal to or greater than the threshold value and the obstacle size is less than the upper limit value. If the obstacle size is greater than or equal to the upper limit value, it is determined as a wall.
- the parking form determination unit 7 can determine the parking form using only the reflection position data groups G1 to G3 corresponding to the vehicle, and can improve the reliability of the determination result.
- FIG. 21 is a flowchart illustrating an example of the operation of the parking form determination device 1.
- steps that perform the same processing as in the flowchart of FIG. 15 are given the same reference numerals, and descriptions thereof are omitted.
- step ST31 the size determination unit 9 receives a plurality of reflection position data divided into the same group from the grouping unit 5, determines the size of the obstacles of the group, and outputs the determination result to the parking form determination unit 7.
- step ST32 the parking pattern determination unit 7 determines the parking pattern and the type of obstacle in this group using the histogram created in step ST16 and the table shown in FIG.
- the parking mode determination unit 7 outputs the determination result of the parking mode to the parking support device 19 when the type of the obstacle is a vehicle.
- the parking mode determination device 1 calculates the distance between the most distant reflection positions among the plurality of reflection positions divided into the same group, and determines the size of the obstacle.
- This is a configuration including the unit 9.
- the parking form determination part 7 is a structure which determines a parking form using the distribution of the inclination angle which the angle calculation part 6 calculated, and the size of the obstruction which the size determination part 9 determined.
- the parking mode can be determined in consideration of the size of the obstacle in addition to the distribution of the inclination angle, and the reliability is improved.
- the size determination unit 9 compares the distance between the most distant reflection positions with a predetermined threshold, and the type of obstacle is from the vehicle, the wall, or the vehicle and the wall. It is the structure which determines which is a small small object. Thereby, a parking form can be determined only based on the group corresponded to a parked vehicle, and reliability improves.
- the parking type determination device automatically determines whether the parking type is parallel parking, parallel parking, or diagonal parking, a parking assistance device that supports the traveling of the vehicle to the parking space, etc. Suitable for use.
- SYMBOLS 1 Parking form determination apparatus 2 Distance measuring part, 3 Vehicle position measuring part, 3-1, 1st distance measuring part, 3-2 2nd distance measuring part, 3-3 Correction value calculation part, 4 Reflection position calculation Unit, 5 grouping unit, 6 angle calculation unit, 7 parking type determination unit, 8 data processing unit, 9 size determination unit, 10 vehicle, 11, 12 distance sensor, 13, 14 wheel speed sensor, 15 yaw rate sensor, 16 GPS Sensor, 17 input device, 18 output device, 19 parking support device, 21 parallel parking vehicle, 22 parallel parking vehicle, 23 diagonal parking vehicle, 30 ECU, 31 transmission / reception circuit, 32 processor, 33 memory.
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Abstract
Description
実施の形態1.
図1は、この発明における駐車形態の判定方法の概要を説明する図である。図1において、車両10は、この発明に係る駐車形態判定装置を搭載した車両である。また、この車両10には、前方の左右に距離センサ11,12が搭載されている。距離センサ11,12は、車両10が縦列駐車車両21、並列駐車車両22および斜め駐車車両23などの駐車車両付近を進行方向Aへ走行しているときに、車両10から側方へ向けて送信波を送信し、障害物である駐車車両で反射した送信波を反射波として受信する。駐車形態判定装置は、距離センサ11,12の送受信結果を用いて、例えば丸印で示したような各反射位置を演算し、これらの反射位置を用いて駐車車両の駐車形態を判定する。
図2の例では、入力装置17は、運転者による駐車形態判定開始の合図を受け付け、距離測定部2および自車位置測定部3へ出力する。また、入力装置17は、車両10のハザードランプの点灯スイッチであって、この点灯スイッチがオンされた場合を駐車形態判定開始の合図として、駐車形態判定開始を指示する信号を距離測定部2および自車位置測定部3へ出力する構成であってもよい。あるいは、入力装置17は、車両10のシフトレバーであって、このシフトレバーがパーキングレンジに操作された場合を駐車形態判定開始の合図として、駐車形態判定開始を指示する信号を距離測定部2および自車位置測定部3へ出力する構成であってもよい。
メモリ33は、例えば、RAM(Random Access Memory)、ROM(Read Only Memory)、フラッシュメモリ、EPROM(Erasable Programmable ROM)、EEPROM(Electrically EPROM)等の不揮発性または揮発性の半導体メモリである。
距離測定部2は、距離センサ11から送信波の送受信結果として、送信波の送信から受信までにかかった時間の情報を受け付ける。そして、距離測定部2は、送受信結果を用いて、車両10の側方の障害物までの距離を測定し、距離データを反射位置演算部4へ出力する。
距離測定部2は、距離センサ12についても上記同様に距離を測定し、距離データを反射位置演算部4へ出力する。
距離センサ11,12は車両10に搭載されている場合が多いため、既設品を利用することができる。あるいは、駐車形態判定装置1が距離センサ11,12を備える構成であってもよい。
GPSセンサ16は車両10に搭載されている場合が多いため、既設品を利用することができる。また、GPSセンサ16を用いた測位により絶対位置が測定できるため、無人走行による自動駐車での利用に有効である。
自車位置測定部3は、車輪速センサ13,14から車両10の車輪速を受け付け、走行速度に変換する。また、自車位置測定部3は、ヨーレートセンサ15から車両10のヨーレートを受け付ける。そして、自車位置測定部3は、ヨーレートから単位時間当たりの進行方向変化量Δθiを演算し、走行速度から単位時間当たりの移動距離ΔDiを演算する。続いて自車位置測定部3は、既知の自車位置(xi-1,yi-1)および方位θi-1と併せて下式(1)、(2)、(3)を用い、現在の自車位置(xi,yi)および方位θiを演算する。
xi=xi-1+ΔDisinθi (2)
yi=yi-1+ΔDicosθi (3)
また、以下に説明する自車位置の測定方法を、後述する実施の形態3に適用した場合、より正確に自車位置を測定することができるため、駐車スペースおよび障害物サイズの計測誤差を抑圧できる。そのため、駐車形態判定の精度が高まる。
車両10が、複数回、距離Dを直進走行した際、GPSセンサ16で複数回それぞれ測定した距離D1にはばらつきがあり、平均値はDとなるものの、標準偏差がσ1となる。式で表すと、D1=D±σ1となる。標準偏差σ1は、電波の受信状況および受信信号の信号対雑音比などで規定される。
他方、複数回、距離Dを直進走行した際、車輪速センサ13,14で複数回それぞれ測定した距離D2にもばらつきがあり、平均値はD-ΔD、標準偏差はσ2となる。式で表すと、D2=D-ΔD±σ2となる。実際の車輪径Rと、車輪速パルスを距離に換算するための車輪径管理値R’が一致しているとき、ΔDはゼロとなる。車輪の空転滑走がない場合、標準偏差σ2はパルス量子化誤差などで規定される。
以上のように、計測誤差が逐次誤差となるGPSセンサ16と、計測誤差が累積誤差となる車輪速センサ13,14の精度が異なるため、GPSセンサ16で測定した距離D1と、車輪速センサ13,14で測定した距離D2に差異が生じる。
R/R’=D/D2 (4)
R=R’×D/D2 (5)
R/R’=D1/D2 (4a)
R=R’×D1/D2 (5a)
さらに、自車位置測定部3は、複数地点で車輪径Rを算出することで、GPSセンサ16で測定した距離D1の標準偏差σ1の影響を小さくすることができる。
なお、センサ位置を演算するために必要な、車両10における距離センサ11,12の設置位置の情報は、反射位置演算部4に予め設定されているものとする。
反射位置演算部4は、最大指向性方向Bにおいて、センサ位置データa1から距離データb1だけ離れた位置を演算し、この位置を反射位置データc1とする。反射位置演算部4は、同様に、センサ位置データa2~a13と距離データb2~b13を用いて、最大指向性方向B上の反射位置c2~c13を演算する。
反射位置演算部4は、センサ位置データa1を中心とし、距離データb1を半径とした円を求める。反射位置演算部4は、同様に、センサ位置データa2を中心とし、距離データb2を半径とした円を求める。そして、反射位置演算部4は、求めた2円の交点位置を演算し、この交点位置を反射位置データc1とする。
具体的には、グループ化部5は、互いに隣接する反射位置データ間の距離が予め定められた閾値以下である場合、当該隣接する各反射位置データを同一グループに入るデータと判定し、隣接する反射位置データ間の距離が予め定められた閾値より大きい場合、当該隣接する反射位置データをそれぞれ別のグループに入るデータと判定する。
あるいは、グループ化部5は、反射位置データの最短距離を基準にして隣接する反射位置データを抽出してもよい。この場合、図4における反射位置データc6に対しては、この反射位置データc6と最短距離の関係にある反射位置データc7が選択され、これら反射位置データc6,c7が互いに隣接する反射位置データとして抽出される。
グループ化部5は、グループ化に用いる閾値を、車両10の走行速度または距離センサ11,12のセンシングの頻度に応じて変更してもよい。グループ化部5は、走行速度が大きいときまたはセンシング頻度が低いとき大きい閾値を用い、走行速度が小さいときまたはセンシング頻度が高いとき小さい閾値を用いる。走行速度またはセンシング頻度と、閾値との対応関係は、グループ化部5に予め設定されているものとする。
なお、角度演算部6は、隣接する反射位置データを、センサ位置データが示す位置を基準にして抽出してもよいし、反射位置データの最短距離を基準にして抽出してもよい。
また、角度演算部6は、2つの反射位置データc4,c5の近似線を求めて、当該近似線の傾き角度θd2を演算する。
角度演算部6は、上記の処理を繰り返し、反射位置データc1~c13のすべてがいずれかの演算には利用されるようにして、傾き角度を演算する。
また、角度演算部6は、2つの反射位置データc4,c5の近似線を求めて、当該近似線の傾き角度θd2を演算する。
角度演算部6は、上記の処理を繰り返し、反射位置データc1~c13のすべてがいずれかの演算には利用されるようにして、傾き角度を演算する。
また、(x1,y1),(x2,y2)は、隣接する2つの反射位置データの座標である。
図9(c)に示すように、傾き角度の分布が、0度の階級に集中している、つまり分布幅が狭い場合は、縦列駐車である。
図10(c)に示すように、傾き角度の分布が、0度の階級付近から広く分散している、つまり分布幅が広い場合は、並列駐車である。
図11(c)に示すように、傾き角度の分布が、正値または負値のどちらかの階級に偏って分散している場合は、斜め駐車である。
駐車形態判定部7は、同一グループの複数の傾き角度を用いて、ヒストグラムを作成する。そして、駐車形態判定部7は、各階級の階級値と度数を用いて、このグループの平均値と分散値を演算する。あるいは、駐車形態判定部7はヒストグラムを作成せずに、同一グループの複数の傾き角度について、平均値および分散値を演算してもよい。
そして、駐車形態判定部7は、平均値が0度であり、分散値が閾値未満であれば、縦列駐車と判定する。また、駐車形態判定部7は、平均値が0度であり、分散値が閾値以上であれば、並列駐車と判定する。また、駐車形態判定部7は、平均値が0度以外であり、分散値が閾値以上であれば、斜め駐車と判定する。
なお、平均値が厳密に0度か否かを判定する必要はなく、0度を含む所定の範囲か否かを判定してもよい。
駐車形態判定部7は、同一グループの複数の傾き角度を用いて、ヒストグラムを作成する。そして、駐車形態判定部7は、最頻値Lとなる階級が0度であり、比率L/Mが閾値(例えば、0.7)以上であれば、縦列駐車と判定する。また、駐車形態判定部7は、最頻値Lとなる階級が0度であり、比率L/Mが閾値未満であれば、並列駐車と判定する。また、駐車形態判定部7は、最頻値Lとなる階級が0度以外であり、比率L/Mが閾値以上であれば、斜め駐車と判定する。
駐車形態判定部7は、同一グループの複数の傾き角度を用いて、ヒストグラムを作成する。そして、駐車形態判定部7は、最頻値Lとなる階級が0度であり、比率O/Lが閾値未満であれば、縦列駐車と判定する。また、駐車形態判定部7は、最頻値Lとなる階級が0度であり、比率O/Lが閾値以上であれば、並列駐車と判定する。また、駐車形態判定部7は、最頻値Lとなる階級が0度以外であり、比率O/Lが閾値未満であれば、斜め駐車と判定する。
また、駐車形態判定部7は、駐車形態の判定結果の信頼性が低いと評価した場合に、その判定結果を出力装置18へ出力して、運転者に判定結果の正誤を問い合わせてもよい。
図15は、駐車形態判定装置1の動作の一例を示すフローチャートである。図15のフローチャートでは、反射位置演算部4において2円交点処理を行い、駐車形態判定部7において第2の方法による駐車形態の判定を行う例を示す。
開始条件を満たす場合、ステップST12において、距離測定部2が距離センサ11,12を用いた距離測定を開始すると共に、自車位置測定部3が車輪速センサ13,14とヨーレートセンサ15、またはGPSセンサ16を用いた自車位置測定を開始する。そして、距離測定部2は反射位置演算部4へ距離データの出力を開始し、自車位置測定部3は反射位置演算部4へ自車位置データの出力を開始する。
あるいは、駐車形態判定の開始条件は、運転者から駐車形態判定開始の合図があったときである。この場合、運転者が入力装置17を操作して駐車形態判定開始の合図を入力すると、入力装置17から距離測定部2および自車位置測定部3へ駐車形態開始を指示する信号が出力される。距離測定部2および自車位置測定部3は、この信号を受け付けると、動作を開始する。
さらに、距離センサ11,12は、超音波式またはレーダ式のいずれであってもよい。超音波式の距離センサは、レーダ式に比べて安価であるため、駐車形態判定装置1を安価に実現することができる。レーダ式の距離センサは、超音波より電波の到達距離が長いため、より遠くの障害物を検出して駐車形態を判定することができる。
図16は、実施の形態2に係る駐車形態判定装置1の構成例を示すブロック図である。実施の形態2に係る駐車形態判定装置1は、図2に示した実施の形態1の駐車形態判定装置1に対して、データ処理部8が追加された構成である。図16において、図1~図15と同一または相当する部分は、同一の符号を付し説明を省略する。
このデータ処理部8は、図3に示したプロセッサ32がメモリ33に格納されたプログラムを実行することにより、実現される。
データ処理部8は、同様に、センサ位置データa11に対しても、距離データb11と反射位置データc11とを補間する。
また、データ処理部8は、閾値判定により削除した反射位置データc5の代わりに、上記補間によって新たに距離データb5と反射位置データc5とを補間してもよい。
図4に示すセンサ位置データa8,a11は距離データと反射位置データが欠落していたため、図17では新たな反射位置データc8,c11が補間されている。
図4に示す反射位置データc1,c2,c7,c9,c11,c12,c13は、近似曲線に一致していないため、図17では近似曲線に一致するよう補正されている。
例えば、データ処理部8は、反射位置データc1が、センサ位置データa1,a2における距離センサ11のセンサ視野角以内であれば有効と判定してグループ化部5へ出力し、センサ視野角以内でなければ無効と判定して削除する。センサ視野角の情報は、データ処理部8に予め設定されているものとする。
具体的には、データ処理部8は、図18において反射位置データc1の最大指向性方向Bに対する角度θe1,θe2が、センサ視野角θe以内であれば、反射位置データc1を有効と判定する。
図19は、実施の形態3に係る駐車形態判定装置1の構成例を示すブロック図である。実施の形態3に係る駐車形態判定装置1は、図2に示した実施の形態1の駐車形態判定装置1に対して、サイズ判定部9が追加された構成である。図19において、図1~図18と同一または相当する部分は、同一の符号を付し説明を省略する。
このサイズ判定部9は、図3に示したプロセッサ32がメモリ33に格納されたプログラムを実行することにより、実現される。
閾値は、障害物をそのサイズにより判定可能な値であり、駐車形態判定部7に予め定められているものとする。車両は、普通自動車、バス、トラックなどの種別によってサイズが異なるため、例えば軽自動車の全幅を下限値(例えば、1m)、トラックの全長を上限値(例えば、5m)とした閾値範囲を定めておき、障害物のサイズが当該閾値範囲内であれば車両、当該閾値範囲未満であれば小物体、当該閾値範囲以上であれば壁と判定する構成とする。
例えば、駐車形態判定部7が上記実施の形態1で説明した第2の方法を用いて駐車形態を判定する場合、図20に示すテーブルが、駐車形態判定部7に予め定められているものとする。
また、駐車形態判定部7は、最頻値Lとなる階級が0度であり、比率L/Mが閾値未満である場合、障害物サイズが下限値(例えば、1m)以上であれば並列駐車車両と判定し、障害物サイズが下限値未満であれば小物体と判定する。
また、駐車形態判定部7は、最頻値Lとなる階級が0度以外であり、比率L/Mが閾値以上である場合、障害物サイズが上限値未満であれば斜め駐車車両と判定し、障害物サイズが上限値以上であれば壁と判定する。
図21は、駐車形態判定装置1の動作の一例を示すフローチャートである。図21において、図15のフローチャートと同一の処理を行うステップには同一の符号を付し、説明を省略する。
Claims (19)
- 距離センサによる送信波の送受信結果を用いて、自車の側方の障害物までの距離を測定する距離測定部と、
前記自車の位置を測定する自車位置測定部と、
前記距離測定部が測定した距離および前記自車位置測定部が測定した自車位置を用いて、送信波の反射位置を演算する反射位置演算部と、
前記反射位置演算部が演算した複数の反射位置を障害物ごとのグループに分けるグループ化部と、
同一グループに分けられた複数の反射位置のうち、隣接する2つ以上の反射位置ごとに近似線を求めて当該近似線の傾き角度または法線の傾き角度を演算する角度演算部と、
同一グループに分けられた複数の反射位置から演算された複数の傾き角度の分布に基づいて、駐車形態が縦列駐車、並列駐車または斜め駐車のいずれであるかを判定する駐車形態判定部とを備える駐車形態判定装置。 - 前記距離センサは、超音波式またはレーダ式であることを特徴とする請求項1記載の駐車形態判定装置。
- 前記自車位置測定部は、GPSを用いて自車位置を測定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記自車位置測定部は、車輪速センサにより検出された走行速度およびヨーレートセンサにより検出されたヨーレートを用いて自車位置を測定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記自車位置測定部は、
計測誤差が逐次誤差となるセンサを用いて前記自車の走行距離を測定する第1の距離測定部と、
計測誤差が累積誤差となるセンサを用いて前記自車の走行距離を測定する第2の距離測定部と、
前記第1の距離測定部が測定した走行距離および前記第2の距離測定部が測定した走行距離を用いて、自車位置測定のための補正値を算出する補正値算出部とを有することを特徴とする請求項1記載の駐車形態判定装置。 - 前記距離測定部および前記自車位置測定部は、前記自車が予め定められた速度以下で走行している場合に動作することを特徴とする請求項1記載の駐車形態判定装置。
- 前記距離測定部および前記自車位置測定部は、駐車形態判定開始を指示する信号を受け付けた場合に動作することを特徴とする請求項1記載の駐車形態判定装置。
- 前記反射位置演算部は、前記距離測定部が測定した距離と、自車位置を用いて演算した距離測定時の前記距離センサの位置と、前記距離センサの指向性が最大になる方向とを用いて、1つの反射位置を演算することを特徴とする請求項1記載の駐車形態判定装置。
- 前記反射位置演算部は、前記距離測定部が測定した距離と、自車位置を用いて演算した距離測定時の前記距離センサの位置とを2組用いて、2円交点処理を行い、1つの反射位置を演算することを特徴とする請求項1記載の駐車形態判定装置。
- 前記2円交点処理により演算された反射位置のうち、距離測定時の前記距離センサのセンサ視野角から外れた反射位置を削除するデータ処理部を備えることを特徴とする請求項9記載の駐車形態判定装置。
- 前記グループ化部は、隣接する反射位置間の距離が予め定められた閾値以下である場合、当該隣接する反射位置を同一グループと判定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記駐車形態判定部は、同一グループの複数の傾き角度の平均値および分散値を演算し、平均値および分散値を用いて駐車形態を判定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記駐車形態判定部は、同一グループの複数の傾き角度のヒストグラムを作成し、傾き角度の総数と最頻値との比率、および最頻値となる階級を用いて駐車形態を判定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記駐車形態判定部は、同一グループの複数の傾き角度のヒストグラムを作成し、最頻値と2番目に度数が多い階級の度数との比率、および最頻値となる階級を用いて駐車形態を判定することを特徴とする請求項1記載の駐車形態判定装置。
- 前記駐車形態判定部は、同一グループに分けられた反射位置の数が多いとき駐車形態の判定結果の信頼性が高いと評価し、反射位置の数が少ないとき駐車形態の判定結果の信頼性が低いと評価することを特徴とする請求項1記載の駐車形態判定装置。
- 前記駐車形態判定部は、複数のグループの駐車形態の判定結果を用いて駐車形態を判定することを特徴とする請求項1記載の駐車形態判定装置。
- 同一グループに分けられた複数の反射位置のうち、最も離れた反射位置間の距離を演算して障害物のサイズを判定するサイズ判定部を備え、
前記駐車形態判定部は、前記角度演算部が演算した傾き角度の分布および前記サイズ判定部が判定した障害物のサイズを用いて駐車形態を判定することを特徴とする請求項1記載の駐車形態判定装置。 - 前記サイズ判定部は、前記最も離れた反射位置間の距離と予め定められた閾値とを比較して、障害物の種類が車両、壁、または車両と壁より小さい小物体のいずれであるかを判定することを特徴とする請求項17記載の駐車形態判定装置。
- 前記自車の側方へ向けて送信波を送受信する距離センサを備えることを特徴とする請求項1記載の駐車形態判定装置。
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JP2019138804A (ja) * | 2018-02-13 | 2019-08-22 | 株式会社デンソーウェーブ | 車両認識装置、車両認識システム、車両認識プログラム |
JP2022111180A (ja) * | 2018-03-06 | 2022-07-29 | トヨタ自動車株式会社 | 駐車支援装置 |
JP2019153226A (ja) * | 2018-03-06 | 2019-09-12 | トヨタ自動車株式会社 | 駐車支援装置 |
CN110228463A (zh) * | 2018-03-06 | 2019-09-13 | 丰田自动车株式会社 | 停车辅助装置 |
JP7283615B2 (ja) | 2018-03-06 | 2023-05-30 | トヨタ自動車株式会社 | 駐車支援装置 |
US11634117B2 (en) | 2018-03-06 | 2023-04-25 | Toyota Jidosha Kabushiki Kaisha | Parking support apparatus |
CN111867893A (zh) * | 2018-03-22 | 2020-10-30 | 日立汽车***株式会社 | 驻车辅助装置 |
JPWO2020230193A1 (ja) * | 2019-05-10 | 2021-09-13 | 三菱電機株式会社 | 駐車形態判定装置 |
WO2020230193A1 (ja) * | 2019-05-10 | 2020-11-19 | 三菱電機株式会社 | 駐車形態判定装置 |
WO2021199098A1 (ja) * | 2020-03-30 | 2021-10-07 | 三菱電機株式会社 | 駐車支援装置 |
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DE112015007005T5 (de) | 2018-06-28 |
JP6272582B2 (ja) | 2018-01-31 |
US20180180731A1 (en) | 2018-06-28 |
CN108137040B (zh) | 2020-12-11 |
US10830885B2 (en) | 2020-11-10 |
DE112015007005B4 (de) | 2021-09-30 |
JPWO2017060975A1 (ja) | 2018-02-01 |
CN108137040A (zh) | 2018-06-08 |
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