WO2014083823A1 - 車両用加速抑制装置及び車両用加速抑制方法 - Google Patents
車両用加速抑制装置及び車両用加速抑制方法 Download PDFInfo
- Publication number
- WO2014083823A1 WO2014083823A1 PCT/JP2013/006881 JP2013006881W WO2014083823A1 WO 2014083823 A1 WO2014083823 A1 WO 2014083823A1 JP 2013006881 W JP2013006881 W JP 2013006881W WO 2014083823 A1 WO2014083823 A1 WO 2014083823A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- parking frame
- acceleration
- host vehicle
- acceleration suppression
- vehicle
- Prior art date
Links
- 238000000034 method Methods 0.000 title claims description 277
- 230000001133 acceleration Effects 0.000 claims abstract description 637
- 230000001629 suppression Effects 0.000 claims abstract description 576
- 238000013459 approach Methods 0.000 claims description 128
- 238000001514 detection method Methods 0.000 claims description 29
- 230000001934 delay Effects 0.000 claims 1
- 230000008569 process Effects 0.000 description 243
- 238000012545 processing Methods 0.000 description 81
- 240000004050 Pentaglottis sempervirens Species 0.000 description 19
- 235000004522 Pentaglottis sempervirens Nutrition 0.000 description 19
- 230000007423 decrease Effects 0.000 description 18
- 238000012546 transfer Methods 0.000 description 18
- 238000010586 diagram Methods 0.000 description 17
- 230000000694 effects Effects 0.000 description 16
- 238000012986 modification Methods 0.000 description 16
- 230000004048 modification Effects 0.000 description 16
- 238000005259 measurement Methods 0.000 description 10
- 230000033228 biological regulation Effects 0.000 description 9
- 230000008859 change Effects 0.000 description 9
- 239000012530 fluid Substances 0.000 description 6
- 230000003111 delayed effect Effects 0.000 description 5
- 238000005070 sampling Methods 0.000 description 5
- 238000003708 edge detection Methods 0.000 description 4
- 230000007935 neutral effect Effects 0.000 description 4
- 230000007704 transition Effects 0.000 description 4
- 125000002066 L-histidyl group Chemical group [H]N1C([H])=NC(C([H])([H])[C@](C(=O)[*])([H])N([H])[H])=C1[H] 0.000 description 3
- 230000009467 reduction Effects 0.000 description 3
- 239000000284 extract Substances 0.000 description 2
- 238000012795 verification Methods 0.000 description 2
- 230000015556 catabolic process Effects 0.000 description 1
- 230000003247 decreasing effect Effects 0.000 description 1
- 238000006731 degradation reaction Methods 0.000 description 1
- 230000000994 depressogenic effect Effects 0.000 description 1
- 230000006866 deterioration Effects 0.000 description 1
- 230000002542 deteriorative effect Effects 0.000 description 1
- 238000000605 extraction Methods 0.000 description 1
- 230000006870 function Effects 0.000 description 1
- 238000003384 imaging method Methods 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 230000002194 synthesizing effect Effects 0.000 description 1
- 230000000007 visual effect Effects 0.000 description 1
Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W50/00—Details of control systems for road vehicle drive control not related to the control of a particular sub-unit, e.g. process diagnostic or vehicle driver interfaces
- B60W50/08—Interaction between the driver and the control system
- B60W50/12—Limiting control by the driver depending on vehicle state, e.g. interlocking means for the control input for preventing unsafe operation
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W30/00—Purposes of road vehicle drive control systems not related to the control of a particular sub-unit, e.g. of systems using conjoint control of vehicle sub-units
- B60W30/08—Active safety systems predicting or avoiding probable or impending collision or attempting to minimise its consequences
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60K—ARRANGEMENT OR MOUNTING OF PROPULSION UNITS OR OF TRANSMISSIONS IN VEHICLES; ARRANGEMENT OR MOUNTING OF PLURAL DIVERSE PRIME-MOVERS IN VEHICLES; AUXILIARY DRIVES FOR VEHICLES; INSTRUMENTATION OR DASHBOARDS FOR VEHICLES; ARRANGEMENTS IN CONNECTION WITH COOLING, AIR INTAKE, GAS EXHAUST OR FUEL SUPPLY OF PROPULSION UNITS IN VEHICLES
- B60K28/00—Safety devices for propulsion-unit control, specially adapted for, or arranged in, vehicles, e.g. preventing fuel supply or ignition in the event of potentially dangerous conditions
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W30/00—Purposes of road vehicle drive control systems not related to the control of a particular sub-unit, e.g. of systems using conjoint control of vehicle sub-units
- B60W30/06—Automatic manoeuvring for parking
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W30/00—Purposes of road vehicle drive control systems not related to the control of a particular sub-unit, e.g. of systems using conjoint control of vehicle sub-units
- B60W30/14—Adaptive cruise control
- B60W30/143—Speed control
- B60W30/146—Speed limiting
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W30/00—Purposes of road vehicle drive control systems not related to the control of a particular sub-unit, e.g. of systems using conjoint control of vehicle sub-units
- B60W30/18—Propelling the vehicle
- B60W30/18009—Propelling the vehicle related to particular drive situations
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W30/00—Purposes of road vehicle drive control systems not related to the control of a particular sub-unit, e.g. of systems using conjoint control of vehicle sub-units
- B60W30/18—Propelling the vehicle
- B60W30/188—Controlling power parameters of the driveline, e.g. determining the required power
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W40/00—Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
- B60W40/02—Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models related to ambient conditions
- B60W40/06—Road conditions
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W40/00—Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models
- B60W40/10—Estimation or calculation of non-directly measurable driving parameters for road vehicle drive control systems not related to the control of a particular sub unit, e.g. by using mathematical models related to vehicle motion
- B60W40/107—Longitudinal acceleration
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D13/00—Control of linear speed; Control of angular speed; Control of acceleration or deceleration, e.g. of a prime mover
- G05D13/62—Control of linear speed; Control of angular speed; Control of acceleration or deceleration, e.g. of a prime mover characterised by the use of electric means, e.g. use of a tachometric dynamo, use of a transducer converting an electric value into a displacement
-
- G—PHYSICS
- G08—SIGNALLING
- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/16—Anti-collision systems
- G08G1/167—Driving aids for lane monitoring, lane changing, e.g. blind spot detection
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60K—ARRANGEMENT OR MOUNTING OF PROPULSION UNITS OR OF TRANSMISSIONS IN VEHICLES; ARRANGEMENT OR MOUNTING OF PLURAL DIVERSE PRIME-MOVERS IN VEHICLES; AUXILIARY DRIVES FOR VEHICLES; INSTRUMENTATION OR DASHBOARDS FOR VEHICLES; ARRANGEMENTS IN CONNECTION WITH COOLING, AIR INTAKE, GAS EXHAUST OR FUEL SUPPLY OF PROPULSION UNITS IN VEHICLES
- B60K31/00—Vehicle fittings, acting on a single sub-unit only, for automatically controlling vehicle speed, i.e. preventing speed from exceeding an arbitrarily established velocity or maintaining speed at a particular velocity, as selected by the vehicle operator
- B60K2031/0091—Speed limiters or speed cutters
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2540/00—Input parameters relating to occupants
- B60W2540/10—Accelerator pedal position
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2720/00—Output or target parameters relating to overall vehicle dynamics
- B60W2720/10—Longitudinal speed
- B60W2720/106—Longitudinal acceleration
Definitions
- the present invention relates to a technique for suppressing acceleration of the host vehicle in order to provide driving assistance during parking.
- the current position of the vehicle (own vehicle) is a position that deviates from the road (such as a public road). Is detected.
- there is an accelerator operation in the direction to increase the vehicle traveling speed and when it is determined that the vehicle traveling speed is greater than the predetermined value, the throttle is decelerated in the deceleration direction regardless of the driver's accelerator operation.
- Patent Document 1 The technique described in Patent Document 1 described above is intended to prevent acceleration of a vehicle that is not intended by the driver even when an accelerator operation error occurs, so whether or not the accelerator operation is an operation error. Judgment is a challenge.
- an erroneous operation of the accelerator occurs under the condition that the vehicle is off the road and the condition in which the accelerator operation is performed in a state in which a traveling speed of a predetermined value or more is detected. It is a condition for determining that there is a possibility.
- control in the throttle deceleration direction is activated depending on the vehicle speed.
- the present invention has been made paying attention to the problems as described above, and suppresses drivability at the time of parking, and can suppress acceleration at the time of erroneous operation of the accelerator, and a vehicle acceleration suppression device. It aims at providing the acceleration suppression method for vehicles.
- an aspect of the present invention detects a traveling direction of the host vehicle, and based on the environment around the host vehicle, the degree of confidence that a parking frame exists in the traveling direction of the host vehicle. The frame certainty is calculated. Then, the higher the detected vehicle speed, the lower the degree of suppression of the host vehicle.
- the parking frame certainty factor in a state where the parking frame certainty factor is low, it is possible to reduce the degree of suppression of acceleration to reduce a decrease in drivability, and in a state where the parking frame certainty factor is high, suppression of acceleration is achieved. It becomes possible to increase the acceleration suppression effect of the host vehicle by increasing the degree. For this reason, while suppressing the drivability at the time of parking, it becomes possible to suppress the acceleration at the time of the erroneous operation of an accelerator.
- FIG. 1 is a conceptual diagram illustrating a configuration of a vehicle including the vehicle acceleration suppression device of the present embodiment.
- the host vehicle V includes wheels W (right front wheel WFR, left front wheel WFL, right rear wheel WRR, left rear wheel WRL), a brake device 2, a fluid pressure circuit 4, and a brake controller 6. Is provided.
- the host vehicle V includes an engine 8 and an engine controller 12.
- the brake device 2 is formed using, for example, a wheel cylinder and provided on each wheel W.
- the brake device 2 is not limited to a device that applies a braking force with fluid pressure, and may be formed using an electric brake device or the like.
- the fluid pressure circuit 4 is a circuit including piping connected to each brake device 2.
- the brake controller 6 responds to the braking force command value generated by each brake device 2 via the fluid pressure circuit 4 based on the braking force command value received from the travel controller 10 that is the host controller. To control the value. That is, the brake controller 6 forms a deceleration control device. In addition, the description regarding the traveling control controller 10 is mentioned later. Therefore, the brake device 2, the fluid pressure circuit 4, and the brake controller 6 form a braking device that generates a braking force.
- the engine 8 forms a drive source for the host vehicle V.
- the engine controller 12 controls the torque (driving force) generated by the engine 8 based on the target throttle opening signal (acceleration command value) received from the travel controller 10. That is, the engine controller 12 forms an acceleration control device. A description regarding the target throttle opening signal will be given later. Therefore, the engine 8 and the engine controller 12 form a driving device that generates driving force.
- the drive source of the own vehicle V is not limited to the engine 8, You may form using an electric motor.
- the driving source of the host vehicle V may be formed by combining the engine 8 and the electric motor.
- FIG. 2 is a block diagram illustrating a schematic configuration of the vehicle acceleration suppression device 1 of the present embodiment.
- the vehicle acceleration suppression device 1 includes an ambient environment recognition sensor 14, a wheel speed sensor 16, a steering angle sensor 18, a shift position sensor 20, and a brake operation detection sensor 22.
- the accelerator operation detection sensor 24 is provided.
- the vehicle acceleration suppression device 1 includes a navigation device 26 and a travel control controller 10.
- the ambient environment recognition sensor 14 captures an image around the host vehicle V, and based on each captured image, an information signal including individual images corresponding to a plurality of imaging directions (in the following description, “individual image signal”). May be written). Then, the generated individual image signal is output to the travel controller 10.
- the surrounding environment recognition sensor 14 is formed using a front camera 14F, a right side camera 14SR, a left side camera 14SL, and a rear camera 14R
- the front camera 14F is a camera that images the front of the host vehicle V in the vehicle front-rear direction
- the right-side camera 14SR is a camera that images the right side of the host vehicle V
- the left-side camera 14SL is a camera that images the left side of the host vehicle V
- the rear camera 14R is a camera that images the rear side of the host vehicle V in the vehicle front-rear direction.
- the wheel speed sensor 16 is formed using, for example, a pulse generator such as a rotary encoder that measures wheel speed pulses. Further, the wheel speed sensor 16 detects the rotational speed of each wheel W, and an information signal including the detected rotational speed (which may be referred to as “wheel speed signal” in the following description) is used as a travel controller. 10 is output.
- the steering angle sensor 18 is provided in a steering column (not shown) that rotatably supports the steering wheel 28.
- the steering angle sensor 18 detects a current steering angle that is a current rotation angle (a steering operation amount) of the steering wheel 28 that is a steering operator.
- an information signal including the detected current steering angle (which may be described as “current steering angle signal” in the following description) is output to the travel controller 10.
- the steering operator is not limited to the steering wheel 28 that is rotated by the driver, and may be, for example, a lever that is operated by the driver to tilt by hand. In this case, the lever tilt angle from the neutral position is output as an information signal corresponding to the current steering angle signal.
- the shift position sensor 20 detects the current position of a member that changes the shift position (for example, “P”, “D”, “R”, etc.) of the host vehicle V, such as a shift knob or a shift lever. Then, an information signal including the detected current position (which may be described as a “shift position signal” in the following description) is output to the travel controller 10.
- the brake operation detection sensor 22 detects the opening degree of the brake pedal 30 that is a braking force instruction operator. Then, an information signal including the detected opening of the brake pedal 30 (in the following description, may be described as “brake opening signal”) is output to the travel controller 10.
- the braking force instruction operator is configured to be operable by the driver of the host vehicle V and to instruct the braking force of the host vehicle V by a change in the opening degree.
- the braking force instruction operator is not limited to the brake pedal 30 that the driver steps on with his / her foot.
- the accelerator operation detection sensor 24 detects the opening degree of the accelerator pedal 32 that is a driving force instruction operator. Then, an information signal including the detected opening of the accelerator pedal 32 (in the following description, it may be described as “accelerator opening signal”) is output to the travel controller 10.
- the driving force instruction operator is configured to be operable by the driver of the host vehicle V and to instruct the driving force of the host vehicle V by changing the opening.
- the driving force instruction operator is not limited to the accelerator pedal 32 that the driver steps on with his / her foot.
- the driving force instruction operator may be a lever operated by the driver with his / her hand.
- the navigation device 26 includes a GPS (Global Positioning System) receiver, a map database, an information presentation device having a display monitor, and the like, and performs route search, route guidance, and the like.
- the navigation device 26 is based on the current position of the host vehicle V acquired using the GPS receiver and the road information stored in the map database, such as the type and width of the road on which the host vehicle V is traveling. Is possible to get.
- the navigation device 26 uses an information signal (which may be referred to as “own vehicle position signal” in the following description) including the current position of the own vehicle V acquired using the GPS receiver, as the traveling control controller 10. Output to.
- the navigation device 26 outputs an information signal including the type of road on which the vehicle V is traveling, the road width, etc. (in the following description, it may be described as “traveling road information signal”) to the travel control controller. 10 is output.
- the information presenting device outputs an alarm or other presenting by voice or image in accordance with a control signal from the travel controller 10.
- the information presentation apparatus includes, for example, a speaker that provides information to the driver by a buzzer sound or voice, and a display unit that provides information by displaying an image or text. Further, the display unit may divert the display monitor of the navigation device 26, for example.
- the travel controller 10 is an electronic control unit that includes CPU peripheral components such as a CPU (Central Processing Unit), ROM (Read Only Memory), and RAM (Random Access Memory).
- the travel controller 10 also includes a parking driving support unit that performs driving support processing for parking.
- the parking driving support unit functionally includes an ambient environment recognition information calculation unit 10A, a host vehicle vehicle speed calculation unit 10B, a steering angle calculation unit 10C, and a steering angular velocity calculation as shown in FIG.
- the processing of unit 10D is provided.
- the parking driving support unit functionally includes a shift position calculation unit 10E, a brake pedal operation information calculation unit 10F, an accelerator operation amount calculation unit 10G, an accelerator operation speed calculation unit 10H, and an acceleration suppression control content calculation unit 10I.
- the parking driving support unit functionally includes processing of an acceleration suppression command value calculation unit 10J and a target throttle opening calculation unit 10K. These functions are composed of one or more programs.
- the surrounding environment recognition information calculation unit 10 ⁇ / b> A forms an image (overhead image) around the host vehicle V viewed from above the host vehicle V based on the individual image signal received from the surrounding environment recognition sensor 14. Then, an information signal including the formed bird's-eye view image (may be described as “bird's-eye view image signal” in the following description) is output to the acceleration suppression control content calculation unit 10I.
- the bird's-eye view image is formed by, for example, synthesizing images captured by the respective cameras (front camera 14F, right side camera 14SR, left side camera 14SL, and rear camera 14R).
- the overhead image includes, for example, an image showing a road marking such as a line of a parking frame displayed on the road surface (may be described as “parking frame line” in the following description).
- the own vehicle vehicle speed calculation unit 10 ⁇ / b> B calculates the speed (vehicle speed) of the own vehicle V from the rotation speed of the wheel W based on the wheel speed signal received from the wheel speed sensor 16. Then, an information signal including the calculated speed (in the following description, may be described as “vehicle speed calculation value signal”) is output to the acceleration suppression control content calculation unit 10I.
- the steering angle calculation unit 10C calculates the operation amount (rotation angle) from the neutral position of the steering wheel 28 from the current rotation angle of the steering wheel 28 based on the current steering angle signal received from the steering angle sensor 18. . Then, an information signal including the calculated operation amount from the neutral position (in the following description, may be described as “steering angle signal”) is output to the acceleration suppression control content calculation unit 10I.
- the steering angular velocity calculation unit 10D calculates the steering angular velocity of the steering wheel 28 by differentiating the current steering angle included in the current steering angle signal received from the steering angle sensor 18. Then, an information signal including the calculated steering angular velocity (may be described as “steering angular velocity signal” in the following description) is output to the acceleration suppression control content calculation unit 10I.
- the shift position calculation unit 10E determines the current shift position based on the shift position signal received from the shift position sensor 20. Then, an information signal including the calculated current shift position (in the following description, may be described as “current shift position signal”) is output to the acceleration suppression control content calculation unit 10I.
- the brake pedal operation information calculation unit 10F calculates the depression amount of the brake pedal 30 based on the state where the depression amount is “0” based on the brake opening signal received from the brake operation detection sensor 22. Then, an information signal including the calculated depression amount of the brake pedal 30 (in the following description, may be described as “braking side depression amount signal”) is output to the acceleration suppression control content calculation unit 10I.
- the accelerator operation amount calculation unit 10G calculates the depression amount of the accelerator pedal 32 with reference to the state where the depression amount is “0” based on the accelerator opening signal received from the accelerator operation detection sensor 24. Then, an information signal including the calculated depression amount of the accelerator pedal 32 (in the following description, may be described as a “driving-side depression amount signal”), an acceleration suppression control content calculation unit 10I, and an acceleration suppression command value calculation To the unit 10J and the target throttle opening calculation unit 10K.
- the accelerator operation speed calculation unit 10H calculates the operation speed of the accelerator pedal 32 by differentiating the opening of the accelerator pedal 32 included in the accelerator opening signal received from the accelerator operation detection sensor 24. Then, an information signal including the calculated operation speed of the accelerator pedal 32 (in the following description, may be described as “accelerator operation speed signal”) is output to the acceleration suppression command value calculation unit 10J.
- the acceleration suppression control content calculation unit 10I includes the above-described various information signals (overhead image signal, vehicle speed calculation value signal, steering angle signal, steering angular velocity signal, current shift position signal, braking side depression amount signal, driving side depression amount signal, Receives input of own vehicle position signal and travel road information signal. And based on the various information signals which received the input, the acceleration suppression operation condition judgment result mentioned later, acceleration suppression control start timing, and acceleration suppression control amount are calculated. Furthermore, an information signal including these calculated parameters is output to the acceleration suppression command value calculation unit 10J. The detailed configuration of the acceleration suppression control content calculation unit 10I and the processing performed by the acceleration suppression control content calculation unit 10I will be described later.
- the acceleration suppression command value calculation unit 10J receives the input of the drive side depression amount signal and the accelerator operation speed signal, and the input of the acceleration suppression operation condition determination result signal, the acceleration suppression control start timing signal, and the acceleration suppression control amount signal described later. receive. And the acceleration suppression command value which is a command value for suppressing the acceleration command value according to the depression amount (driving force operation amount) of the accelerator pedal 32 is calculated. Further, an information signal including the calculated acceleration suppression command value (may be described as an “acceleration suppression command value signal” in the following description) is output to the target throttle opening calculation unit 10K. Further, the acceleration suppression command value calculation unit 10J calculates a normal acceleration command value, which is a command value used in normal acceleration control, according to the content of the received acceleration suppression operation condition determination result signal. Furthermore, an information signal including the calculated normal acceleration command value (in the following description, may be described as “normal acceleration command value signal”) is output to the target throttle opening calculation unit 10K. The processing performed by the acceleration suppression command value calculation unit 10J will be described later.
- the target throttle opening calculation unit 10K receives a drive side depression amount signal and an acceleration suppression command value signal or a normal acceleration command value signal. Based on the depression amount of the accelerator pedal 32 and the acceleration suppression command value or the normal acceleration command value, a target throttle opening that is a throttle opening corresponding to the depression amount of the accelerator pedal 32 or the acceleration suppression command value is calculated. Further, an information signal including the calculated target throttle opening (in the following description, may be described as “target throttle opening signal”) is output to the engine controller 12. Further, when the acceleration suppression command value includes an acceleration suppression control start timing command value described later, the target throttle opening calculation unit 10K sends the target throttle opening signal to the engine controller 12 based on the acceleration suppression control start timing described later. Output. The processing performed by the target throttle opening calculation unit 10K will be described later.
- FIG. 3 is a block diagram illustrating a configuration of the acceleration suppression control content calculation unit 10I.
- the acceleration suppression control content calculation unit 10I includes an acceleration suppression operation condition determination unit 34, a parking frame certainty factor calculation unit 36, a parking frame approach certainty factor calculation unit 38, and an overall certainty factor calculation unit. 40.
- the acceleration suppression control content calculation unit 10I includes an acceleration suppression control start timing calculation unit 42 and an acceleration suppression control amount calculation unit 44.
- the acceleration suppression operation condition determination unit 34 determines whether or not a condition for operating acceleration suppression control is satisfied, and describes an information signal including the determination result (in the following description, “acceleration suppression operation condition determination result signal”). Is output to the acceleration suppression command value calculation unit 10J.
- the acceleration suppression control is a control for suppressing an acceleration command value for accelerating the host vehicle V in accordance with the depression amount of the accelerator pedal 32. The process in which the acceleration suppression operation condition determination unit 34 determines whether the condition for operating the acceleration suppression control is satisfied will be described later.
- the parking frame certainty calculation unit 36 calculates a parking frame certainty factor indicating the degree of certainty that the parking frame exists in the traveling direction of the host vehicle V. Then, an information signal including the calculated parking frame certainty factor (in the following description, may be described as “parking frame certainty signal”) is output to the total certainty factor calculation unit 40.
- the parking frame certainty calculation unit 36 calculates the parking frame certainty by referring to various information included in the bird's-eye view image signal, the vehicle speed calculation value signal, the current shift position signal, the own vehicle position signal, and the traveling road information signal. To do.
- FIG. 4 for example, there are a plurality of patterns in the parking frame that the parking frame certainty factor calculation unit 36 calculates the certainty factor.
- FIG. 4 is a figure which shows the pattern of the parking frame which the parking frame reliability calculation part 36 makes calculation object of parking frame reliability.
- the process which the parking frame reliability calculation part 36 calculates parking frame reliability is mentioned later.
- the parking frame approach reliability calculation unit 38 calculates a parking frame approach reliability that indicates the degree of confidence that the host vehicle V enters the parking frame. Then, an information signal including the calculated parking frame approach certainty factor (in the following description, may be described as a “parking frame approach certainty signal”) is output to the total confidence factor calculation unit 40.
- the parking frame approach certainty factor calculation unit 38 calculates the parking frame approach certainty factor with reference to various information included in the overhead image signal, the vehicle speed calculation value signal, the current shift position signal, and the steering angle signal. In addition, the process which the parking frame approach reliability calculation part 38 calculates a parking frame approach reliability is mentioned later.
- the total certainty calculation unit 40 receives the input of the parking frame certainty signal and the parking frame approach certainty signal, and calculates the total certainty indicating the degree of comprehensive confidence between the parking frame certainty and the parking frame approach certainty. To do. Then, an information signal including the calculated total certainty factor (may be described as a “total certainty factor signal” in the following description) is output to the acceleration suppression control start timing calculation unit 42 and the acceleration suppression control amount calculation unit 44. To do. In addition, the process which the comprehensive reliability calculation part 40 calculates a comprehensive reliability is mentioned later.
- the acceleration suppression control start timing calculation unit 42 calculates an acceleration suppression control start timing that is a timing for starting the acceleration suppression control. Then, an information signal including the calculated acceleration suppression control start timing (may be described as “acceleration suppression control start timing signal” in the following description) is output to the acceleration suppression command value calculation unit 10J.
- the acceleration suppression control start timing calculation unit 42 refers to various information included in the comprehensive certainty signal, the braking side depression amount signal, the vehicle speed calculation value signal, the current shift position signal, and the steering angle signal, and starts the acceleration suppression control. Calculate timing. The process in which the acceleration suppression control start timing calculation unit 42 calculates the acceleration suppression control start timing will be described later.
- the acceleration suppression control amount calculation unit 44 calculates an acceleration suppression control amount that is a control amount for suppressing the acceleration command value according to the depression amount of the accelerator pedal 32. Then, an information signal including the calculated acceleration suppression control amount (in the following description, may be described as “acceleration suppression control amount signal”) is output to the acceleration suppression command value calculation unit 10J.
- the acceleration suppression control amount calculation unit 44 refers to various information included in the comprehensive certainty signal, the braking side depression amount signal, the vehicle speed calculation value signal, the current shift position signal, and the steering angle signal, and determines the acceleration suppression control amount. Calculate. The process in which the acceleration suppression control amount calculation unit 44 calculates the acceleration suppression control amount will be described later.
- FIG. 5 is a flowchart illustrating processing in which the acceleration suppression operation condition determination unit 34 determines whether or not the acceleration suppression operation condition is satisfied.
- the acceleration suppression operation condition determination unit 34 performs the process described below for each preset sampling time (for example, 10 [msec]).
- step S100 a process for acquiring an image around the host vehicle V (“host vehicle surroundings” shown in the figure). Image acquisition processing ”). If the process which acquires the image around the own vehicle V is performed in step S100, the process which the acceleration suppression operation condition judgment part 34 performs will transfer to step S102.
- the surrounding image of the own vehicle V is acquired with reference to an overhead image around the own vehicle V included in the overhead image signal received from the surrounding environment recognition information calculation unit 10A.
- step S102 based on the image acquired in step S100, a process for determining the presence / absence of a parking frame (“parking frame presence / absence determination process" shown in the figure) is performed.
- the process for determining the presence or absence of a parking frame is, for example, whether or not there is a white line (parking frame line) or the like that identifies the parking frame within a distance or area (area) set in advance with reference to the host vehicle V. Judge whether or not.
- various well-known systems such as edge detection, are used, for example.
- FIG. 6 is a schematic diagram schematically illustrating a parking frame line recognition method based on edge detection.
- FIG. 6A when the parking frame lines Lm and Ln are detected, scanning in the horizontal direction is performed in the area indicating the captured image.
- scanning an image for example, a monochrome image obtained by binarizing a captured image is used.
- FIG. 6A shows a captured image. Since the parking frame line is displayed in white or the like sufficiently brighter than the road surface, the brightness is higher than that of the road surface.
- FIG. 6B is a graph showing the luminance change of the pixels in the image when scanning from the left to the right.
- FIG. 6C is the same as FIG. 6A. It is a figure which shows the done image. Further, in FIG. 6B, the plus edge is indicated by a sign “E + ”, and in FIG. 6C, the plus edge is indicated by a thick solid line with a sign “E + ”).
- a negative edge at which the luminance decreases rapidly is detected at the boundary portion where the parking frame line changes to the road surface.
- the minus edge is indicated by a sign “E ⁇ ”
- the minus edge is indicated by a thick dotted line with a sign “E ⁇ ”.
- the parking frame line is detected by detecting a pair of adjacent edges in the order of plus edge (E + ) and minus edge (E ⁇ ) in the scanning direction. Judge that it exists.
- step S102 when it is determined in step S102 that there is no parking frame ("No" shown in the figure), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S120.
- step S104 a process for acquiring the vehicle speed of the host vehicle V ("own vehicle speed information acquisition process" shown in the figure) is performed with reference to the vehicle speed calculation value signal received from the host vehicle speed calculation unit 10B. If the process which acquires the vehicle speed of the own vehicle V is performed in step S104, the process which the acceleration suppression operation condition judgment part 34 performs will transfer to step S106.
- step S106 based on the vehicle speed acquired in step S104, it is determined whether or not a condition that the vehicle speed of the host vehicle V is less than a preset threshold vehicle speed is satisfied ("own vehicle vehicle speed shown in the figure”). "Condition judgment process”).
- the threshold vehicle speed is set to 15 [km / h]
- the threshold vehicle speed is not limited to 15 [km / h], and may be changed according to the specifications of the host vehicle V such as the braking performance of the host vehicle V, for example. Further, for example, the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels. If it is determined in step S106 that the condition that the vehicle speed of the host vehicle V is less than the threshold vehicle speed is satisfied ("Yes" shown in the figure), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S108. Transition.
- step S106 determines whether the condition that the vehicle speed of the host vehicle V is less than the threshold vehicle speed is not satisfied ("No" shown in the drawing).
- step S108 referring to the brake-side depression amount signal received from the brake pedal operation information calculation unit 10F, a process of obtaining information on the depression amount (operation amount) of the brake pedal 30 ("brake pedal shown in the drawing" Operation amount information acquisition processing ”) is performed.
- step S108 when the process of acquiring information on the depression amount (operation amount) of the brake pedal 30 is performed, the process performed by the acceleration suppression operation condition determination unit 34 proceeds to step S110.
- step S110 based on the depression amount of the brake pedal 30 acquired in step S108, a process for determining whether or not the brake pedal 30 is operated (“brake pedal operation determination process" shown in the figure) is performed.
- step S110 If it is determined in step S110 that the brake pedal 30 has not been operated ("No” shown in the figure), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S112. On the other hand, when it is determined in step S110 that the brake pedal 30 is operated (“Yes” shown in the drawing), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S120.
- step S112 With reference to the drive side depression amount signal received from the accelerator operation amount calculation unit 10G, information on the depression amount (operation amount) of the accelerator pedal 32 is acquired ("accelerator pedal operation shown in the figure"). Quantity information acquisition processing ”). If the process which acquires the information of the depression amount (operation amount) of the accelerator pedal 32 is performed in step S112, the process which the acceleration suppression operation condition judgment part 34 performs will transfer to step S114.
- step S114 a process for determining whether or not a condition that the depression amount (operation amount) of the accelerator pedal 32 is equal to or larger than a preset threshold accelerator operation amount is satisfied ("accelerator pedal operation determination process" shown in the figure). )I do.
- the process of step S114 is performed based on the depression amount of the accelerator pedal 32 acquired in step S112.
- the threshold accelerator operation amount is set to an operation amount corresponding to 3% of the opening of the accelerator pedal 32.
- the threshold accelerator operation amount is not limited to the operation amount corresponding to 3% of the opening degree of the accelerator pedal 32. It may be changed.
- step S114 processing for acquiring information for determining whether or not the host vehicle V enters the parking frame ("parking frame entry determination information acquisition processing" shown in the figure) is performed.
- parking frame entry determination information acquisition processing processing for acquiring information for determining whether or not the host vehicle V enters the parking frame.
- the process performed by the acceleration suppression operation condition determination unit 34 proceeds to step S118.
- step S116 the rotation angle (steering angle) of the steering wheel 28 is acquired with reference to the steering angle signal received from the steering angle calculation unit 10C.
- the angle ⁇ between the host vehicle V and the parking frame L0, the host vehicle V, and The distance D with the parking frame L0 is acquired.
- the angle ⁇ is an absolute value of the intersection angle between the straight line X and the line on the frame line L1 and the parking frame L0 side.
- FIG. 7 is a figure explaining the distance D of the own vehicle V, the parking frame L0, and the own vehicle V and the parking frame L0.
- the straight line X is a straight line in the front-rear direction of the host vehicle V that passes through the center of the host vehicle V (a straight line extending in the traveling direction). It is a frame line of the parking frame L0 part which becomes parallel or substantially parallel to the front-back direction.
- the line on the parking frame L0 side is a line on the parking frame L0 side that is an extension of L1.
- the distance D is, for example, the distance between the center point PF of the front end face of the host vehicle V and the center point PP of the entrance L2 of the parking frame L0 as shown in FIG. However, the distance D is a negative value after the front end surface of the host vehicle V passes through the entrance L2 of the parking frame L0.
- the distance D may be set to zero after the front end surface of the host vehicle V passes through the entrance L2 of the parking frame L0.
- the position on the own vehicle V side for specifying the distance D is not limited to the center point PF, and may be, for example, a position set in advance in the own vehicle V and a preset position in the entrance L2.
- the distance D is a distance between a position set in advance in the host vehicle V and a position set in advance at the entrance L2.
- step S116 as information for determining whether or not the host vehicle V enters the parking frame L0, the steering angle, the angle ⁇ between the host vehicle V and the parking frame L0, the host vehicle V and the parking The distance D of the frame L0 is acquired.
- step S118 based on the information acquired in step S116, a process for determining whether or not the host vehicle V enters the parking frame ("parking frame entry determining process" shown in the figure) is performed. If it is determined in step S118 that the host vehicle V does not enter the parking frame ("No" shown in the figure), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S120. On the other hand, if it is determined in step S118 that the host vehicle V enters the parking frame ("Yes" shown in the figure), the processing performed by the acceleration suppression operation condition determination unit 34 proceeds to step S122.
- step S118 for example, when all of the following three conditions (A1 to A3) are satisfied, it is determined that the host vehicle V enters the parking frame.
- Condition A1 The elapsed time after the steering angle detected in step S116 is equal to or greater than a preset steering angle value (eg, 45 [deg]) is within a preset setup time (eg, 20 [sec]). is there.
- the angle ⁇ between the host vehicle V and the parking frame L0 is a preset angle (for example, 40 [deg]) or less.
- Condition A3 The distance D between the host vehicle V and the parking frame L0 is equal to or less than a preset set distance (for example, 3 [m]).
- step S120 an acceleration suppression operation condition determination result signal is generated as an information signal including a determination result that the acceleration suppression control operation condition is not satisfied ("acceleration suppression operation condition not satisfied" shown in the drawing). If the process which produces
- step S122 a process of generating an acceleration suppression operation condition determination result signal as an information signal including a determination result that the acceleration suppression control operation condition is satisfied ("acceleration suppression operation condition satisfaction" shown in the figure) is performed. If the process which produces
- step S124 a process of outputting the acceleration suppression operation condition determination result signal generated in step S120 or step S122 to the acceleration suppression command value calculation unit 10J ("acceleration suppression operation condition determination result output" shown in the drawing) is performed. If the process which outputs an acceleration suppression operation condition judgment result signal to the acceleration suppression command value calculating part 10J is performed in step S124, the process which the acceleration suppression operation condition judgment part 34 performs will return to the process of step S100 (RETURN).
- FIG. 8 is a flowchart showing a process in which the parking frame certainty calculation unit 36 calculates the parking frame certainty.
- the parking frame reliability calculation part 36 performs the process demonstrated below for every preset sampling time (for example, 10 [msec]).
- START when the parking frame certainty calculation unit 36 starts the process (START), first, in step S200, a process of calculating (setting) the level of the parking frame certainty as the lowest value (level 0). ("Level 0" shown in the figure) is performed. If the process which calculates parking frame reliability as the level 0 is performed in step S200, the process which the parking frame reliability calculation part 36 performs will transfer to step S202.
- step S202 a process of acquiring a bird's-eye view image around the host vehicle V included in the bird's-eye view image signal received from the surrounding environment recognition information calculation unit 10A ("Ambient image acquisition" shown in the figure) is performed. If the process which acquires the bird's-eye view image around the own vehicle V is performed in step S202, the process which the parking frame reliability calculation part 36 performs will transfer to step S204.
- step S204 the process (“determination element extraction” shown in the figure) which extracts the determination element used in order to calculate parking frame reliability is performed from the bird's-eye view image acquired by step S202. If the process which extracts the determination element from a bird's-eye view image is performed in step S204, the process which the parking frame reliability calculation part 36 performs will transfer to step S206.
- the determination element is a line (white line, etc.) marked on the road surface, such as a parking frame line, and the state satisfies, for example, all of the following three conditions (B1 to B3) Then, the line is extracted as a determination element.
- Condition B1 If the marked line on the road surface has a broken part, the broken part is a part where the marked line is faint (for example, a part having a lower clarity than the line and a higher clarity than the road surface). ).
- Condition B2 The width of the line marked on the road surface is not less than a preset setting width (for example, 10 [cm]).
- the setting width is not limited to 10 [cm], and may be changed according to traffic regulations or the like of the area (country or the like) in which the host vehicle V is traveling.
- Condition B3 The length of the line marked on the road surface is greater than or equal to a preset set line length (for example, 2.5 [m]).
- the set marking line length is not limited to 2.5 [m], and may be changed according to traffic regulations or the like of the area (country or the like) in which the host vehicle V is traveling.
- step S206 a process of determining whether or not the determination element extracted in step S204 conforms to the conditions of the line forming the parking frame line (“parking frame condition conformance?” Shown in the figure) is performed.
- step S206 when it is determined that the determination element extracted in step S204 does not conform to the conditions of the line forming the parking frame line ("No" shown in the drawing), the parking frame certainty calculation unit 36 performs it. The process proceeds to step S200.
- the parking frame certainty calculation unit 36 proceeds to step S208.
- the process performed by step S206 is performed with reference to the overhead image signal received from 10 A of surrounding environment recognition information calculating parts, for example.
- FIG. 9 is a figure which shows the content of the process which the parking frame reliability calculation part 36 performs.
- a region indicating an image captured by the front camera 14 ⁇ / b> F in the overhead view image is denoted by a symbol “PE”.
- PE a region indicating an image captured by the front camera 14 ⁇ / b> F in the overhead view image.
- step S206 first, two adjacent lines displayed on the same screen are identified as one set from the lines marked on the road surface which is the determination element extracted in step S204 (in the following description). , Sometimes referred to as “pairing”). When three or more lines are displayed on the same screen, two or more pairs are specified by two adjacent lines for the three or more lines.
- the determination element extracted in step S204 is the line that forms the parking frame line. Judge that the condition is met.
- the width WL between two paired lines is a preset pairing width (for example, 2.5 [m]) or less.
- the set pairing width is not limited to 2.5 [m], and may be changed, for example, according to traffic regulations or the like of the area (country or the like) in which the host vehicle V is traveling.
- the angle (degree of parallelism) formed by the line La and the line Lb is within a preset set angle (for example, 3 [°]).
- the set angle is not limited to 3 [°], and may be changed according to, for example, the recognition ability of the surrounding environment recognition sensor 14.
- a reference line (a line extending in the vertical direction of the region PE) is indicated by a dotted line with a reference “CLc”, and a central axis of the line La is indicated by a reference “CLa”.
- the central axis of the line Lb is indicated by a broken line with the sign “CLb”.
- the inclination angle of the central axis line CLa with respect to the reference line CLc is indicated by a symbol “ ⁇ a”
- the inclination angle of the central axis line CLb with respect to the reference line CLc is indicated by a reference symbol “ ⁇ b”. Therefore, if the conditional expression of
- Condition C3 As shown in FIG. 9C, a straight line connecting the end of the line La on the own vehicle V side (the end on the lower side in the drawing) and the end of the line Lb on the own vehicle V side, and the own vehicle
- the angle ⁇ formed with the line L closer to V is equal to or larger than a preset setting deviation angle (for example, 45 [°]).
- the setting deviation angle is not limited to 45 [°], and may be changed according to, for example, the recognition ability of the surrounding environment recognition sensor 14.
- Condition C4 As shown in FIG.
- ) of the difference between the width W0 of the line La and the width W1 of the line Lb is a preset line width (for example, 10 [cm]) )
- the set line width is not limited to 10 [cm], and may be changed according to, for example, the recognition ability of the surrounding environment recognition sensor 14.
- step S208 a process for determining whether or not the process in step S206 is continuously verified from the start of the process in step S206 until the moving distance of the host vehicle V reaches the preset moving distance (see FIG. "Continuous verification matching?") Shown in the inside.
- the set moving distance is set in the range of 1 to 2.5 [m], for example, according to the specifications of the host vehicle V.
- the processing performed in step S208 is performed with reference to, for example, an overhead image signal received from the surrounding environment recognition information calculation unit 10A and a vehicle speed calculation value signal received from the host vehicle vehicle speed calculation unit 10B.
- step S208 If it is determined in step S208 that the processing in step S206 is not continuously collated ("No" shown in the figure), the processing performed by the parking frame certainty calculation unit 36 proceeds to step S210. On the other hand, if it is determined in step S208 that the processing in step S206 is continuously collated (“Yes” shown in the figure), the processing performed by the parking frame certainty calculation unit 36 proceeds to step S212.
- the process performed in step S208 for example, as shown in FIG. 10, the moving distance of the host vehicle V is set according to the state in which the process in step S206 is collated and the state in which the process in step S206 is not collated. Operate virtually.
- FIG. 10 is a figure which shows the content of the process which the parking frame reliability calculation part 36 performs. In FIG.
- step S206 when the state in which the process in step S ⁇ b> 206 is collated is “ON”, the virtual travel distance increases.
- the state checked in step S206 is “OFF”, the virtual travel distance decreases.
- the slope (increase gain) when the virtual travel distance increases is set larger than the slope (decrease gain) when the virtual travel distance decreases. That is, if the “verification state” is “ON” and the “OFF” state is the same time, the virtual travel distance increases. Then, when the virtual travel distance reaches the set travel distance without returning to the initial value (shown as “0 [m]” in the figure), it is determined that the processing in step S206 is continuously verified.
- step S210 processing ("level 1" shown in the figure) is performed to calculate the level of parking frame certainty as a level (level 1) that is one step higher than the lowest value (level 0). If the process which calculates parking frame reliability as level 1 is performed in step S210, the process which the parking frame reliability calculation part 36 performs will be complete
- step S212 the end points located on the same side with respect to the host vehicle V (the end point on the near side or the end point on the far side) with respect to the lines La and Lb that are continuously collated in the process of step S206 Is detected.
- step S212 a process of determining whether or not the end points located on the same side face each other along the direction of the width WL (“approaching near and far end point?” Shown in the figure) is performed.
- the process performed in step S212 is performed with reference to, for example, an overhead image signal received from the surrounding environment recognition information calculation unit 10A and a vehicle speed calculation value signal received from the host vehicle vehicle speed calculation unit 10B.
- step S212 when it is determined that the end points located on the same side do not face each other along the direction of the width WL ("No" shown in the drawing), the process performed by the parking frame certainty calculation unit 36 is as follows. Control goes to step S214. On the other hand, if it is determined in step S212 that the end points located on the same side face each other along the direction of the width WL (“Yes” shown in the drawing), the parking frame certainty calculation unit 36 performs processing. Proceeds to step S216. In step S214, a process (“level 2" shown in the figure) is performed to calculate the level of parking frame certainty as a level (level 2) that is two levels higher than the lowest value (level 0). If the process which calculates parking frame reliability as level 2 is performed in step S214, the process which the parking frame reliability calculation part 36 performs will be complete
- step S216 in the process of step S212, the end points located on the other side are further detected with respect to the lines La and Lb that are determined that the end points located on the same side face each other along the direction of the width WL.
- step S212 when an end point on the side closer to the lines La and Lb (one side) is detected, an end point on the side farther from the lines La and Lb (the other side) is detected in step S216.
- step S216 To detect.
- a process of determining whether or not the end points located on the other side face each other along the direction of the width WL (“end-to-end end point matching?” Shown in the figure) is performed.
- the process performed in step S216 is performed with reference to, for example, an overhead image signal received from the surrounding environment recognition information calculation unit 10A and a vehicle speed calculation value signal received from the host vehicle vehicle speed calculation unit 10B.
- Intersection points are not processed (recognized) as end points. This is because, when detecting the end point, the end point is detected by scanning in the horizontal direction in the region indicating the captured image. Further, for example, the area indicated by the white frame in FIG. 4 (p) indicates an object on the road such as a pillar, and therefore the end point of this object is not detected.
- step S216 when it is determined that the end points located on the other side do not face each other along the direction of the width WL ("No" shown in the drawing), the process performed by the parking frame certainty calculation unit 36 is performed. The process proceeds to step S218.
- step S216 when it is determined that the end points located on the other side face each other along the direction of the width WL ("Yes” shown in the drawing), the parking frame certainty calculation unit 36 performs the operation. The process proceeds to step S220.
- step S220 a process (“level 4" shown in the figure) is performed to calculate the level of parking frame certainty as a level (level 4) that is four levels higher than the lowest value (level 0). If the process which calculates parking frame reliability as level 4 is performed in step S220, the process which the parking frame reliability calculation part 36 performs will be complete
- the parking frame certainty factor is a parking frame that is likely to be marked on a public road, in particular, when the pattern shown in FIG. 4A is specified, or other than the pattern shown in FIG. 4A If the parking frame cannot be specified, it may be restricted as follows according to the width of the parking frame. Specifically, for example, if the width of the parking frame is 2.6 [m] or less, the certainty of the parking frame is maintained at the initially calculated level, but the width of the parking frame exceeds 2.6 [m]. If so, the parking frame certainty factor is limited so that it is not calculated as level 3 or higher. Thereby, it is set as the structure which the double-sided broken line marked on the public road is hard to be detected as a parking frame line.
- FIG. 11 is a flowchart showing a process in which the parking frame approach certainty calculator 38 calculates the parking frame approach certainty factor.
- the parking frame approach reliability calculation part 38 performs the process demonstrated below for every preset sampling time (for example, 10 [msec]).
- FIG. 11 when the parking frame approach certainty calculation unit 38 starts processing (START), first, in step S300, processing for detecting a deviation amount between the predicted rear wheel trajectory of the host vehicle V and the parking frame. (“Shift amount detection" shown in the figure) is performed.
- step S300 If the process which detects the deviation
- the unit of deviation detected in step S300 is [cm].
- the width of a parking frame is 2.5 [m] is demonstrated as an example.
- the expected rear wheel trajectory TR of the host vehicle V is calculated, and the intersection of the calculated expected rear wheel trajectory TR and the entrance L2 of the parking frame L0.
- TP is calculated.
- a distance Lfl between the left frame line L1l of the parking frame L0 and the intersection TP and a distance Lfr between the right frame line L1r of the parking frame L0 and the intersection TP are calculated, and the distance Lfl and the distance Lfr are compared.
- the longer one of the distance Lfl and the distance Lfr is detected as a deviation amount between the predicted rear wheel trajectory TR of the host vehicle V and the parking frame L0.
- FIG. 12 is a diagram showing the contents of processing for detecting the amount of deviation between the predicted rear wheel trajectory TR of the host vehicle V and the parking frame L0.
- the center point PR in the vehicle width direction of the right rear wheel WRR and the left rear wheel WRL of the host vehicle V is used as the reference point of the host vehicle V.
- the virtual movement path of the center point PR is calculated using the images taken by the front camera 14F and the left camera 14SL in the overhead view image, the vehicle speed of the host vehicle V, and the rotation angle (steering angle) of the steering wheel 28.
- a predicted rear wheel trajectory TR is calculated.
- step S302 for example, processing for detecting parallelism between the straight line X and the length direction (for example, the depth direction) of the parking frame L0 using an image captured by the front camera 14F among the overhead images (shown in the figure). “Parallelity detection”). If the process which detects the parallelism of the straight line X and the length direction of the parking frame L0 is performed in step S302, the process which the parking frame approach reliability calculation part 38 performs will transfer to step S304.
- the parallelism detected in step S302 is detected as an angle ⁇ ap formed by the center line Y and the straight line X of the parking frame L0 as shown in FIG.
- step S302 when the host vehicle V moves to the parking frame L0 while moving backward, for example, using the image captured by the rear camera 14R in the overhead view image, the straight line X and the length direction of the parking frame L0 are used. Processing to detect parallelism is performed.
- the moving direction (forward, backward) of the host vehicle V is detected with reference to a current shift position signal, for example.
- step S304 processing for calculating the turning radius of the host vehicle V ("turning radius calculation” shown in the figure) is performed using the vehicle speed of the host vehicle V and the rotation angle (steering angle) of the steering wheel 28. If the process which calculates the turning radius of the own vehicle V is performed in step S304, the process which the parking frame approach reliability calculation part 38 performs will transfer to step S306. In step S306, it is determined whether or not the parallelism ( ⁇ ap) detected in step S302 is less than a preset parallelism threshold (for example, 15 [°]) (“parallelism ⁇ parallel” shown in the figure). Degree threshold? ").
- a preset parallelism threshold for example, 15 [°]
- step S306 If it is determined in step S306 that the parallelism ( ⁇ ap) detected in step S302 is equal to or greater than the parallelism threshold (“No” in the figure), the process performed by the parking frame approach certainty calculator 38 is performed in step S308. Migrate to
- step S306 when it is determined in step S306 that the parallelism ( ⁇ ap) detected in step S302 is less than the parallelism threshold (“Yes” shown in the figure), the process performed by the parking frame approach certainty calculation unit 38 is as follows. The process proceeds to step S310. In step S308, it is determined whether or not the turning radius detected in step S304 is greater than or equal to a preset turning radius threshold (for example, 100 [R]) (“turning radius ⁇ turning radius threshold? ”)I do. If it is determined in step S308 that the turning radius detected in step S304 is less than the turning radius threshold value ("No" shown in the figure), the processing performed by the parking frame approach certainty calculation unit 38 proceeds to step S312. .
- a preset turning radius threshold for example, 100 [R]
- step S310 a process for determining whether or not the amount of deviation detected in step S300 is greater than or equal to a preset first threshold (for example, 75 [cm]) (“deviation amount ⁇ first threshold? ”)I do.
- the first threshold value is not limited to 75 [cm], and may be changed according to the specifications of the host vehicle V, for example. If it is determined in step S310 that the amount of deviation detected in step S300 is greater than or equal to the first threshold ("Yes" shown in the figure), the processing performed by the parking frame approach certainty calculator 38 proceeds to step S314. .
- step S310 determines whether or not the amount of deviation detected in step S300 is less than the first threshold (“No" shown in the figure).
- step S316 a process for determining whether or not the deviation amount detected in step S300 is greater than or equal to a preset second threshold (for example, 150 [cm]) (“deviation amount ⁇ second threshold? ")I do.
- the second threshold value is larger than the first threshold value described above.
- the second threshold value is not limited to 150 [cm], and may be changed according to the specifications of the host vehicle V, for example.
- step S312 when it is determined that the amount of deviation detected in step S300 is greater than or equal to the second threshold ("Yes" shown in the figure), the process performed by the parking frame approach certainty calculator 38 proceeds to step S318. .
- step S312 determines whether the amount of deviation detected in step S300 is less than the second threshold ("No" shown in the figure). If it is determined in step S312 that the amount of deviation detected in step S300 is less than the second threshold ("No" shown in the figure), the process performed by the parking frame approach certainty calculator 38 proceeds to step S314. Transition.
- the structure of the own vehicle V is a structure provided with the apparatus (parking assistance apparatus) which assists steering operation to the parking frame L0 with respect to a driver
- operator for example, if a parking assistance apparatus is an ON state, it will park. It is good also as a structure which becomes easy to raise the level of frame approach reliability.
- a parking assistance device for example, in order to perform parking, a device that displays a monitor of surrounding conditions with a bird's-eye view image, etc., or a target parking on a screen in order to guide a course for parking There is a device to set the position. These devices are used by operating a switch for switching a screen in order to display a surrounding situation as a bird's-eye view image or a screen switching switch for setting a target parking position on the screen. And if these switches are operated, it will be set as the structure which a parking assistance apparatus will be in an ON state.
- the parking assist device is in the ON state even when the parking frame approach certainty factor is calculated as “level 0” in the process of step S318.
- the parking frame approach reliability is corrected to “low level”.
- the parking frame approach reliability is set to “high level”. It is the structure correct
- a level at which the parking frame approach reliability is set in advance (for example, “level high”) It is good also as a structure calculated as.
- the overall certainty calculation unit 40 receives the input of the parking frame certainty signal and the parking frame approach certainty signal, and receives the parking frame certainty included in the parking frame certainty signal and the parking frame entering certainty included in the parking frame approach certainty signal.
- the degree is adapted to the comprehensive certainty calculation map shown in FIG.
- FIG. 13 is a figure which shows a comprehensive reliability calculation map. Further, in FIG.
- the parking frame certainty factor is denoted as “frame certainty factor”, and the parking frame approach certainty factor is denoted as “entry certainty factor”. 13 is a map used when the host vehicle V travels forward. As an example of the process of calculating the total certainty factor by the total certainty factor calculation unit 40, when the parking frame certainty factor is “level 3” and the parking frame approach certainty factor is “high level”, it is shown in FIG. Thus, the total certainty factor is calculated as “high”.
- the total confidence factor calculation unit 40 when the total confidence factor calculation unit 40 performs a process of calculating the total confidence factor, the calculated total confidence factor is stored in a storage unit in which data is not erased even when the ignition switch is turned off.
- the storage unit from which data is not erased even when the ignition switch is turned off is, for example, a ROM or the like. Therefore, in the present embodiment, when the ignition switch is turned off after completion of parking of the host vehicle V, and the ignition switch is turned on when the host vehicle V restarts, the total certainty factor calculated immediately before is stored. . For this reason, it becomes possible to start the control based on the total certainty calculated immediately before the ignition switch is turned on when the host vehicle V restarts.
- FIG. 14 is a diagram showing an acceleration suppression condition calculation map.
- the acceleration suppression control start timing is indicated as “suppression control start timing (accelerator opening)” in the “acceleration suppression condition” column.
- the acceleration suppression control start timing is increased by increasing the opening of the accelerator pedal 32 as shown in FIG. Then, the timing is set to reach “50%”.
- the opening degree of the accelerator pedal 32 is set to 100% when the accelerator pedal 32 is depressed (operated) to the maximum value.
- the acceleration suppression control start timing shown in FIG. 14 is an example, and may be changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example. Further, for example, the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels.
- the acceleration suppression control amount calculation unit 44 receives the input of the total certainty factor signal, and adapts the total certainty factor included in the total certainty factor signal to the acceleration suppression condition calculation map shown in FIG. Then, an acceleration suppression control amount is calculated based on the total certainty factor.
- the acceleration suppression control amount is indicated as “suppression amount” in the “acceleration suppression condition” column.
- the acceleration suppression control amount is set to the actual opening degree of the accelerator pedal 32 as shown in FIG.
- the control amount is set to be suppressed to the “medium” level throttle opening.
- the throttle opening at the “medium” level is the throttle opening at which the actual opening of the accelerator pedal 32 is suppressed to 25%.
- the throttle opening at the “small” level is the throttle opening at which the actual opening of the accelerator pedal 32 is suppressed to 50%
- the throttle opening at the “large” level is the opening of the actual accelerator pedal 32.
- the throttle opening is such that the degree is suppressed to 10%.
- the acceleration suppression control amount shown in FIG. 14 is an example, and may be changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example. Further, for example, the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels. Further, the acceleration suppression control amount calculation unit 44 sets the presence / absence of control to output a warning sound by adapting the total certainty factor to the acceleration suppression condition calculation map. In the case of outputting a warning sound, for example, character information on the content that activates the acceleration suppression control and visual information such as a symbol and light emission may be displayed on a display monitor included in the navigation device 26.
- FIG. 15 is a flowchart showing processing performed by the acceleration suppression command value calculation unit 10J.
- the acceleration suppression command value calculation unit 10J performs the processing described below for each preset sampling time (for example, 10 [msec]).
- a preset sampling time for example, 10 [msec]
- FIG. 15 when the acceleration suppression command value calculation unit 10J starts processing (START), first, in step S400, an acceleration suppression operation condition determination result signal received from the acceleration suppression control content calculation unit 10I is displayed. refer. And the process (“acceleration suppression operation condition judgment result acquisition process" shown in the figure) which acquires an acceleration suppression operation condition judgment result is performed. If the process which acquires an acceleration suppression operation condition judgment result is performed in step S400, the process which the acceleration suppression command value calculating part 10J performs will transfer to step S402.
- step S402 in addition to the acceleration suppression operation condition determination result acquired in step S400, processing for acquiring information for calculating the acceleration suppression command value ("acceleration suppression command value calculation information acquisition processing" shown in the figure) is performed. . If the process which acquires the information for calculating an acceleration suppression command value in step S402 is performed, the process which the acceleration suppression command value calculating part 10J performs will transfer to step S404.
- the information for calculating the acceleration suppression command value is, for example, information included in the acceleration suppression control start timing signal, the acceleration suppression control amount signal, the drive side depression amount signal, and the accelerator operation speed signal described above.
- step S404 a process of determining whether or not the acceleration suppression operation condition determination result acquired in step S400 is a determination result that the acceleration suppression control operation condition is satisfied (“acceleration suppression control operation condition satisfied?” Shown in the figure). Do. If it is determined in step S404 that the acceleration suppression control operation condition is satisfied ("Yes" shown in the figure), the processing performed by the acceleration suppression command value calculation unit 10J proceeds to step S406.
- step S404 determines whether the acceleration suppression control operation condition is not satisfied ("No" shown in the figure).
- step S404 determines whether the acceleration suppression control operation condition is not satisfied ("No" shown in the figure).
- step S406 based on the information for calculating the acceleration suppression command value acquired in step S402, a process of calculating an acceleration suppression command value that is an acceleration command value for performing acceleration suppression control ("Acceleration suppression command shown in the figure"). Control command value calculation "). If the process which calculates an acceleration suppression command value is performed in step S406, the process which the acceleration suppression command value calculating part 10J performs will transfer to step S410.
- an acceleration suppression control amount command value for calculating the throttle opening degree as a suppression degree (see FIG. 14) corresponding to the acceleration suppression control amount with respect to the actual opening degree of the accelerator pedal 32 is calculated.
- step S408 driving force control without acceleration suppression control, that is, processing for calculating a normal acceleration command value that is an acceleration command value used in normal acceleration control ("command value calculation for normal acceleration control" shown in the figure). I do. If the process which calculates a normal acceleration command value is performed in step S408, the process which the acceleration suppression command value calculating part 10J performs will transfer to step S412.
- step S410 an acceleration suppression command value signal including the acceleration suppression command value calculated in step S406 is output to the target throttle opening calculation unit 10K ("acceleration suppression command value output" shown in the figure). If the process which outputs an acceleration suppression command value signal is performed in step S410, the process which the acceleration suppression command value calculating part 10J performs will be complete
- step S412 a process of outputting a normal acceleration command value signal including the normal acceleration command value calculated in step S408 to the target throttle opening calculation unit 10K ("normal acceleration command value output" shown in the figure) is performed. If the process which outputs a normal acceleration command value signal is performed in step S412, the process which the acceleration suppression command value calculating part 10J performs will be complete
- FIG. 16 is a flowchart showing processing performed by the target throttle opening calculation unit 10K.
- the target throttle opening calculation unit 10K performs the process described below for each preset sampling time (for example, 10 [msec]).
- the target throttle opening calculation unit 10K starts processing (START)
- step S500 the drive side depression amount signal received from the accelerator operation amount calculation unit 10G is referred to.
- step S500 the drive side depression amount signal received from the accelerator operation amount calculation unit 10G is referred to.
- the process (“accelerator operation amount acquisition process” shown in a figure) which acquires the depression amount (operation amount) of the accelerator pedal 32 which the drive side depression amount signal contains is performed. If the process which acquires the depression amount (operation amount) of the accelerator pedal 32 is performed in step S500, the process which the target throttle opening calculating part 10K performs will transfer to step S502.
- step S502 an acceleration suppression command value (see step S406) or a normal acceleration command value (see step S408) is acquired based on the information signal received from the acceleration suppression command value calculation unit 10J (see “ Command value acquisition processing ”). If the process which acquires an acceleration suppression command value or a normal acceleration command value is performed in step S502, the process which the target throttle opening calculating part 10K performs will transfer to step S504. In step S504, calculation of the target throttle opening (“target throttle opening calculation" shown in the figure) is performed based on the depression amount of the accelerator pedal 32 acquired in step S500 and the command value acquired in step S502. When the target throttle opening is calculated in step S504, the processing performed by the target throttle opening calculation unit 10K proceeds to step S506.
- step S504 when the command value acquired in step S502 is a normal acceleration command value (when the acceleration suppression operation condition is not established), the throttle opening corresponding to the depression amount of the accelerator pedal 32 is set as follows. Calculated as the target throttle opening.
- the command value acquired in step S502 is the acceleration suppression command value (when the acceleration suppression operation condition is satisfied)
- the throttle opening corresponding to the acceleration suppression control amount command value is set as the target throttle opening.
- the target throttle opening is calculated using, for example, the following equation (1).
- ⁇ * ⁇ 1 ⁇ (1)
- the target throttle opening is indicated by “ ⁇ * ”
- the throttle opening corresponding to the depression amount of the accelerator pedal 32 is indicated by “ ⁇ 1”
- the acceleration suppression control amount is indicated by “ ⁇ ”.
- step S506 a target throttle opening signal including the target throttle opening ⁇ * calculated in step S504 is output to the engine controller 12 (“target throttle opening output” shown in the figure).
- target throttle opening output shown in the figure.
- the process performed by the target throttle opening calculation unit 10K ends (END).
- the command value acquired in step S502 is an acceleration suppression command value
- the opening (depression amount) of the accelerator pedal 32 reaches the opening corresponding to the acceleration suppression control start timing.
- the target throttle opening signal is output.
- the parking frame L0 When the vehicle speed is less than the threshold vehicle speed, the parking frame L0 is detected, the brake pedal 30 is not operated, and the depression amount of the accelerator pedal 32 is greater than or equal to the threshold accelerator operation amount, the host vehicle V moves to the parking frame L0. Judge whether to enter or not. Further, while the host vehicle V is traveling, the parking frame certainty calculation unit 36 calculates the parking frame certainty factor, and the parking frame approach certainty calculating unit 38 calculates the parking frame approach certainty factor. And the comprehensive reliability calculation part 40 calculates the comprehensive reliability based on a parking frame reliability and a parking frame approach reliability.
- the acceleration suppression control start timing calculation unit 42 calculates the acceleration suppression control start timing based on the total reliability calculated by the total reliability calculation unit 40, and the acceleration suppression control amount calculation unit 44 calculates an acceleration suppression control amount.
- the acceleration suppression command value calculation unit 10J outputs an acceleration suppression command value signal to the target throttle opening calculation unit 10K.
- the target throttle opening calculation unit 10K outputs a target throttle opening signal to the engine controller 12. Therefore, when the driver operates the accelerator pedal 32 in a state where the acceleration suppression control operation condition is satisfied, the throttle opening corresponding to the depression amount of the accelerator pedal 32 is changed to the opening corresponding to the acceleration suppression control amount command value. Suppress.
- the start timing for suppressing the throttle opening according to the depression amount of the accelerator pedal 32 is set as the timing according to the acceleration suppression control start timing command value.
- the acceleration suppression amount (the degree of throttle opening suppression) is small when the overall confidence level is low, it is possible to reduce the reduction in drivability, and when the overall confidence level is high, the acceleration suppression amount is large. Therefore, the acceleration suppression effect of the host vehicle V can be increased.
- the acceleration of the host vehicle V is suppressed and the safety is improved by increasing the acceleration suppression control amount as the total certainty factor is higher. Further, the lower the overall certainty, the later the acceleration suppression control start timing is delayed, and the drivability is suppressed from decreasing. This makes it possible to improve safety and suppress deterioration of drivability under the following conditions. For example, in the situation where the host vehicle V standing by in the vicinity of the parking frame L0 for parallel parking on the side of the traveling road is started, it is necessary to allow a certain degree of acceleration. Even under the following conditions, it is necessary to allow a certain amount of acceleration.
- the acceleration suppression control start timing and the acceleration suppression control amount By controlling the acceleration suppression control start timing and the acceleration suppression control amount based on the total certainty for these situations, it is possible to suppress the acceleration of the host vehicle V and improve safety. In addition, it is possible to allow acceleration of the host vehicle V and suppress a reduction in drivability.
- the acceleration suppression control amount when the parking frame certainty factor is low, the acceleration suppression control amount is calculated to be smaller than when the parking frame certainty factor is high. As a result, as described below, it is possible to suppress drivability degradation under the situation where the current position of the host vehicle V is not on a public road (for example, in a parking lot).
- a line is detected in the image captured by the surrounding environment recognition sensor 14, but the detected line cannot be identified as a parking frame line.
- the parking frame certainty is calculated as a low level.
- the case where the detected line cannot be identified as the parking frame line is, for example, that one line is detected in the image captured by the surrounding environment recognition sensor 14 and its end is detected. This is a case where a line is not detected on the near side of the book line (the side close to the host vehicle V).
- the current position of the host vehicle V is It is determined that the position is not on a public road, and the parking frame certainty is calculated as a low level. This is because the lines marked on public roads are often regularly maintained by public institutions, etc., so if the edge is blurred or the period when it is blurred and unclear is short This is because it can be estimated.
- the acceleration suppression command value calculation unit 10J and the target throttle opening calculation unit 10K described above correspond to an acceleration control unit.
- the ambient environment recognition information calculation unit 10A described above corresponds to the ambient environment recognition unit.
- the host vehicle speed calculation unit 10B, the steering angle calculation unit 10C, the steering angular speed calculation unit 10D, the brake pedal operation information calculation unit 10F, the accelerator operation amount calculation unit 10G, and the accelerator operation speed calculation unit 10H described above are included in the host vehicle running state.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K described above correspond to the acceleration suppression unit.
- the throttle opening described above corresponds to the acceleration command value.
- corresponds to the own vehicle present position detection part and the own vehicle traveling path type detection part.
- the vehicle acceleration suppression method implemented by the operation of the vehicle acceleration suppression device 1 according to the present embodiment is more effective when the parking frame certainty factor is low than when the parking frame certainty factor is high.
- This is a method of suppressing the acceleration command value corresponding to the operation amount of the pedal 32 with a low suppression degree.
- the parking frame certainty factor indicates the degree of certainty that the parking frame L0 exists in the traveling direction of the host vehicle V, and is calculated based on the environment around the host vehicle V.
- the acceleration suppression method for a vehicle implemented by the operation of the vehicle acceleration suppression device 1 according to the present embodiment has a lower accelerator pedal 32 when the total certainty factor is low than when the total certainty factor is high.
- the comprehensive certainty indicates the degree of comprehensive certainty between the parking frame certainty and the parking frame approach certainty.
- the parking frame approach reliability indicates the degree of confidence that the host vehicle V enters the parking frame L0.
- the parking frame certainty calculation unit 36 calculates the parking frame certainty based on the bird's-eye view image (environment) around the host vehicle V and the vehicle speed (running state) of the host vehicle V. In addition to this, when the parking frame certainty factor calculated by the parking frame certainty factor calculation unit 36 is low, the degree of suppression of the acceleration command value is made lower than when the parking frame certainty factor is high. That is, when the parking frame certainty factor calculated by the parking frame certainty factor calculation unit 36 is high, the degree of suppression of the acceleration command value is increased compared to when the parking frame certainty factor is low.
- the parking frame certainty factor when the parking frame certainty factor is low, it is possible to reduce the degree of suppression of the acceleration command value to reduce the decrease in drivability, and when the parking frame certainty factor is high, the degree of suppression of the acceleration command value can be reduced.
- the acceleration suppression effect of the host vehicle V can be increased by increasing the speed. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the parking frame approach reliability calculation unit 38 determines the parking frame approach reliability based on the bird's-eye view image (environment) around the host vehicle V, the vehicle speed of the host vehicle V, and the rotation angle (running state) of the steering wheel 28. Calculate the degree.
- the overall certainty factor calculating unit 40 is based on the parking frame certainty factor calculated by the parking frame certainty factor calculating unit 36 and the parking frame approach certainty factor calculated by the parking frame approach certainty factor calculating unit 38. Is calculated. Furthermore, when the total certainty factor calculated by the total certainty factor calculation unit 40 is low, the degree of suppression of the acceleration command value is made lower than when the total certainty factor is high.
- the degree of suppression of the acceleration command value can be controlled according to the certainty degree that the own vehicle V enters the parking frame L0. It becomes possible. As a result, in addition to the effect (1) described above, it is possible to further suppress the drivability of the host vehicle V during parking and to suppress the acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K delay the acceleration suppression control start timing to lower the degree of suppression of the acceleration command value. .
- the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K reduce the acceleration suppression control amount to lower the degree of suppression of the acceleration command value.
- the degree of suppression of the acceleration command value can be controlled by controlling the amount of throttle opening suppression according to the amount of depression of the accelerator pedal 32.
- the parking frame certainty factor is calculated based on an overhead image (environment) around the host vehicle V and the vehicle speed (running state) of the host vehicle V.
- the acceleration command value is suppressed with a lower suppression degree when the parking frame certainty factor is low than when the parking frame certainty factor is high.
- the parking frame certainty factor is low, it is possible to reduce the degree of suppression of the acceleration command value to reduce the decrease in drivability, and when the parking frame certainty factor is high, the degree of suppression of the acceleration command value can be reduced.
- the acceleration suppression effect of the host vehicle V can be increased by increasing the speed. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the parking frame approach reliability is calculated based on an overhead image (environment) around the host vehicle V and the vehicle speed (running state) of the host vehicle V.
- the total certainty is calculated.
- the degree of suppression of the acceleration command value can be controlled according to the certainty degree that the own vehicle V enters the parking frame L0. It becomes possible.
- the acceleration suppression control start timing and the acceleration suppression control amount are calculated based on the total reliability calculated by the total reliability calculation unit 40.
- the present invention is not limited to this.
- the acceleration suppression control start timing and the acceleration suppression control amount may be calculated based only on the parking frame reliability calculated by the parking frame reliability calculation unit 36.
- the acceleration suppression control start timing and the acceleration suppression control amount are calculated by adapting the parking frame certainty to, for example, an acceleration suppression condition calculation map shown in FIG.
- FIG. 17 is a diagram illustrating a modification of the present embodiment.
- the configuration of the parking frame certainty calculation unit 36 is calculated based on the bird's-eye view image (environment) around the host vehicle V and the vehicle speed (running state) of the host vehicle V.
- the configuration of the parking frame certainty calculation unit 36 is not limited to this. That is, the configuration of the parking frame certainty calculation unit 36 is added to the current position of the host vehicle V included in the host vehicle position signal and the host vehicle included in the traveling road information signal in addition to the overhead view image and the vehicle speed around the host vehicle V. It is good also as a structure which calculates parking frame reliability using the classification (road classification) of the road which V drive
- the parking frame certainty factor is calculated as “level 0”.
- the parking frame certainty level is set. 3 or 4 is calculated (see step S212).
- the process of calculating the parking frame certainty level as level 3 or level 4 is not limited to this. That is, the shape of the end point of the line L is not marked on the public road, for example, when it is U-shaped (see FIGS. 4 (g) to (k), (m), (n)). If this is recognized, the parking frame certainty may be calculated as level 3 or level 4.
- the configuration of the parking frame certainty calculation unit 36 is calculated based on the bird's-eye view image (environment) around the host vehicle V and the vehicle speed (running state) of the host vehicle V.
- the configuration of the parking frame certainty calculation unit 36 is not limited to this. That is, if the configuration of the host vehicle V is, for example, a configuration that includes a device (parking support device) that assists the driver in steering to the parking frame L0, and the parking support device is in the ON state, parking is performed. It is good also as a structure which becomes easy to raise the level of frame reliability.
- the configuration in which the level of the parking frame certainty is likely to increase is, for example, a configuration in which the above-described set movement distance is set to a shorter distance than usual.
- a parking assistance apparatus for example, in order to perform parking, an apparatus that monitors and displays the surrounding situation with a bird's-eye view image, etc., or a parking position that is a target on the screen to guide a course for parking
- These devices are used by operating a switch for switching a screen in order to display a surrounding situation as a bird's-eye view image or a screen switching switch for setting a target parking position on the screen. And when these switches are operated and a parking assistance apparatus will be in an ON state, it is good also as a structure which makes it easy to detect a parking frame and becomes easy to raise the level of parking frame reliability.
- step S206 there is a method of correcting the set value so that the above-described conditions C1 to C4 in step S206 are easily established.
- step S206 there is a method of setting a short set movement distance used when it is determined that the continuous collation state has reached the set movement distance.
- step S212 there is a setting method in which the condition of the endpoint when determining “level 3” or “level 4”, for example, the number of endpoints may be smaller than the initial setting.
- the parking frame reliability is detected as a preset level (for example, “level 4”) regardless of the actual detection status of the parking frame. A method may be used.
- the acceleration suppression control amount and the acceleration suppression control start timing are changed based on the total certainty factor to change the suppression degree of the acceleration command value.
- the present invention is not limited to this. That is, according to the total certainty factor, only the acceleration suppression control start timing or only the acceleration suppression control amount may be changed to change the suppression degree of the acceleration command value. In this case, for example, as the total certainty factor is higher, the acceleration suppression control amount may be set larger, and the suppression degree of the acceleration command value may be increased without changing the acceleration suppression control start timing.
- the total certainty factor is calculated.
- the present invention is not limited to this. That is, for example, the total certainty factor may be calculated according to the number of lines L detected when the above-described condition B is satisfied.
- the number of lines L detected when the condition B is satisfied is adapted to the comprehensive certainty factor calculation map shown in FIG.
- the total certainty factor is calculated.
- FIG. 18 is a diagram showing a comprehensive certainty calculation map used in a modification of the present embodiment. In FIG. 18, as in FIG. 13, the parking frame certainty factor is indicated as “frame certainty factor”, and the parking frame approach certainty factor is indicated as “entry certainty factor”.
- the parking frame approach certainty is “low level” and the parking frame certainty is calculated as “level 1” and when calculated as “level 2 to 4”
- the total certainty factor is calculated according to the type of the line L detected when the condition B is satisfied.
- the type of the line L detected when the condition B is satisfied is a single line In the same manner as in the case of “level 0”, it is calculated as the total certainty that the acceleration suppression control is not performed.
- the parking frame approach reliability is “low level” and the parking frame reliability is calculated as “level 1”
- the type of the line L detected when the condition B is satisfied is a double line. Calculates the total confidence as “very low”.
- the type of the line L detected when the condition B is satisfied is a single line. Calculates the total confidence as “very low”. Further, when the parking frame approach reliability is “low level” and the parking frame reliability is calculated as “level 2 to 4”, the type of the line L detected when the condition B is satisfied is a double line. In this case, the total certainty factor is calculated as “extremely high”.
- the total certainty factor is calculated using the total certainty factor calculation map shown in FIG. 18, for example, the calculated total certainty factor is adapted to the acceleration suppression condition calculation map shown in FIG. Calculate the control start timing.
- FIG. 19 is a figure which shows the acceleration suppression condition calculation map used in the modification of this embodiment.
- the acceleration suppression control start timing is indicated as “suppression control start timing (accelerator opening)” in the “acceleration suppression condition” column.
- the acceleration suppression control start timing is set to the opening of the accelerator pedal 32. Time measurement starts when the degree increases to reach “80%”. In addition, the time when the measurement time when the opening degree of the accelerator pedal 32 is “80%” or more reaches “0.25 [sec]” is set as the acceleration suppression control start timing. That is, when the total certainty factor is “very low”, the acceleration is started from the time when the measurement time when the opening degree of the accelerator pedal 32 is “80%” or more reaches “0.25 [sec]”. Start suppression control.
- the acceleration suppression control amount when the total certainty factor is “extremely low” is set to a control amount that is suppressed to the throttle opening of the “small” level.
- the acceleration suppression control amount is indicated as “suppression amount” in the “acceleration suppression condition” column.
- the acceleration suppression control start timing starts measuring time when the accelerator pedal 32 opening degree reaches “50%”.
- the time when the measurement time when the opening of the accelerator pedal 32 is “50%” or more reaches “0.65 [sec]” is set as the acceleration suppression control start timing. That is, when the total certainty factor is “extremely high”, the acceleration is started from the time when the measurement time when the opening degree of the accelerator pedal 32 is “50%” or more reaches “0.65 [sec]”. Start suppression control.
- the acceleration suppression control amount when the total certainty factor is “extremely high” is set to a control amount that is suppressed to the throttle opening at the “large” level.
- FIG. 20 is a diagram illustrating the relationship between the acceleration suppression control start timing and the holding time.
- the acceleration suppression control start timing is indicated as “accelerator opening [%]” on the horizontal axis
- the holding time is indicated as “holding time [sec]” on the vertical axis.
- acceleration suppression control starts at the point PH when the measurement time when the accelerator opening is “50%” or more reaches “0.65 [sec]” Set as timing.
- a line that continuously indicates a control threshold value that is a setting reference for the acceleration suppression control start timing is indicated by a solid line.
- the type of the line L detected when the condition B is satisfied may change.
- the type of the line L detected when the condition B is satisfied changes from a single line to a double line in a situation where the parking frame certainty factor is calculated as “level 2 to 4”.
- the total certainty level changes from “very low” to “very high”.
- the time point PL shown in FIG. 20 is set as the acceleration suppression control start timing until the accelerator opening reaches 80%. Does not start the measurement of the holding time.
- the time to start acceleration suppression control is delayed compared to the case where the overall confidence level was calculated as “very high” from the beginning. It becomes. For this reason, for example, when the host vehicle V traveling in a parking lot having a configuration in which a plurality of parking frames are arranged, such as tower parking, travels on an uphill slope when moving from a lower-level parking lot to an upper-level parking lot. In such a situation, it is possible to suppress a decrease in drivability.
- the parking frame certainty is calculated as “level 0” by delaying the timing at which the acceleration suppression control is started, compared to the case where the total certainty is calculated as “extremely high” from the beginning.
- the time when the vehicle travels on a high climb slope is defined as the time when acceleration suppression control is started.
- the parking frame certainty factor is calculated as “level 2 to 4”
- the type of the line L detected when the condition B is satisfied is a single line
- the parking frame approach certainty factor is “level”
- the overall reliability changes from “very low” to “very high”.
- the overall confidence is accelerated as compared with the case where the total certainty is calculated as “extremely high” from the beginning. The time for starting the suppression control will be delayed.
- the overall confidence is calculated as "very high” from the beginning even if the overall confidence changes from "very low” to "very high”.
- the time for starting the acceleration suppression control is delayed as compared with the case where it has been. As a result, it is more likely to decelerate on public roads by delaying the timing at which acceleration suppression control is started than when the total certainty was calculated as “extremely high” from the beginning.
- the time at which acceleration suppression control is started is the time at which acceleration suppression control is started.
- the acceleration command value is controlled to suppress the acceleration of the host vehicle V according to the depression amount (driving force operation amount) of the accelerator pedal 32.
- the present invention is not limited to this. That is, for example, the throttle opening corresponding to the depression amount (driving force operation amount) of the accelerator pedal 32 is set as the target throttle opening, and further, the braking force is generated by the braking device described above, and the driving force operation amount is determined. The acceleration of the host vehicle V may be suppressed.
- the parking frame certainty factor is calculated as level 0, which is the lowest value, and levels higher than the lowest value (levels 1 to 4).
- the present invention is not limited to this. In other words, the parking frame certainty factor may be calculated as only two levels: a level that is the lowest value (for example, “level 0”) and a level that is higher than the lowest value (for example, “level 100”).
- the parking frame approach reliability is calculated as “level 0” as the lowest value, “level low” at a level higher than level 0, and “level high” at a level higher than level low.
- the parking frame approach reliability level is not limited to this. That is, the parking frame approach reliability may be calculated as only two levels: a level that is the lowest value (for example, “level 0”) and a level that is higher than the lowest value (for example, “level 100”).
- the overall confidence level is divided into four levels according to the parking frame confidence level calculated as one of the five levels and the parking frame approach reliability level calculated as one of the three levels.
- Level (“very low”, “low”, “high”, “very high”).
- the overall confidence level is not limited to this.
- the total certainty factor may be calculated as only two levels: a level that is the lowest value (for example, “level 0”) and a level that is higher than the lowest value (for example, “level 100”).
- the total certainty factor is calculated as the lowest level.
- the total certainty factor is calculated as a level higher than the minimum value.
- the present embodiment a second embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described with reference to the drawings.
- the configuration of the vehicle acceleration suppression device 1 of the present embodiment will be described with reference to FIGS. 1 to 20 and FIGS. 21 and 22.
- the vehicle acceleration suppression device 1 of the present embodiment is the same as that of the first embodiment described above except for the processing performed by the acceleration suppression control content calculation unit 10I. Therefore, except for the processing performed by the acceleration suppression control content calculation unit 10I. The description may be omitted.
- the parking frame certainty factor calculation unit 36 of the present embodiment first determines whether the traveling direction of the host vehicle V is forward or backward, and is set according to the determination result. Set the travel distance. Then, based on the set travel distance set in accordance with the traveling direction of the host vehicle V, the process in step S206 continues from the start of the process in step S206 until the travel distance of the host vehicle V becomes the set travel distance. To determine whether to collate.
- the process of setting the set movement distance according to the traveling direction of the host vehicle V is performed with reference to the current shift position signal received from the shift position calculation unit 10E, for example.
- the set moving distance is set to 2.5 [m], and it is determined that the traveling direction of the host vehicle V is backward. Then, the case where a set movement distance is set to 1 [m] is demonstrated.
- the set travel distance is an example, and may be changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example. Further, for example, the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels.
- the parking frame reliability calculation part 36 of this embodiment determines first whether the advancing direction of the own vehicle V is advancing or retreating in the process of step S212 mentioned above. And when the advancing direction of the own vehicle V is forward, like the first embodiment described above, if it is determined that the end points located on the same side face each other along the direction of the width WL, The processing performed by the frame certainty calculation unit 36 is shifted to step S216.
- step S216 when the traveling direction of the host vehicle V is backward, one end point shape of the lines La and Lb is, for example, U-shaped (FIGS. 4 (g) to (k), (m), (n) If it is recognized that the parking frame certainty factor calculation unit 36 performs, the process proceeds to step S216. That is, when the traveling direction of the host vehicle V is backward, when the end point shape of the lines La and Lb is recognized as a shape that is not marked on the public road, the parking frame certainty calculation unit 36 The processing to be performed is shifted to step S216. Therefore, in the present embodiment, in the process of step S212, when the traveling direction of the host vehicle V is forward, the level of the parking frame certainty is “level 3” than when the traveling direction of the host vehicle V is backward. It becomes difficult to calculate as.
- the overall certainty calculation unit 40 of the present embodiment receives the parking frame certainty signal and the parking frame approach certainty signal, receives the parking frame certainty factor included in the parking frame certainty signal, and the parking frame approach certainty signal.
- the parking frame approach reliability included in is adapted to the comprehensive reliability calculation map shown in FIG. Then, based on the parking frame certainty factor and the parking frame approach certainty factor, the total certainty factor is calculated.
- FIG. 21 is a diagram showing an overall certainty factor calculation map used in the present embodiment. Further, in FIG. 21, as in FIG. 13, the parking frame certainty factor is denoted as “frame certainty factor”, and the parking frame approach certainty factor is denoted as “entry certainty factor”.
- the comprehensive certainty calculation map used by the comprehensive certainty calculation unit 40 of the present embodiment is different from the comprehensive certainty calculation map used by the comprehensive certainty calculation unit 40 of the first embodiment described above.
- the total confidence level is changed according to the direction determination result. Note that, in FIG. 21, the total certainty when it is determined that the traveling direction of the host vehicle V is forward is indicated as “low forward level” and “high forward level” in the “entry certainty” column. . In addition to this, in FIG. 21, the total certainty when it is determined that the traveling direction of the host vehicle V is backward is “reverse level high” and “reverse level high” in the “entry certainty” column. It shows.
- the overall certainty factor calculation unit 40 of the present embodiment determines the total certainty factor when the traveling direction of the host vehicle V is backward, and the traveling direction of the host vehicle V advances. It is calculated as a level that is equal to or greater than the total certainty when it is determined that
- the total certainty factor is calculated as “low”.
- the parking frame certainty level is “level 2” and the parking frame approaching certainty level is “high level during backward movement”
- the total certainty level is calculated as “high” as shown in FIG.
- the parking frame reliability is calculated as “level 1” while the host vehicle V is moving forward, and then the host vehicle V moves backward and is moving backward within a predetermined distance (for example, 2.5 [m]). Apply again when moving forward.
- the acceleration suppression control start timing calculation unit 42 of the present embodiment determines that the traveling direction of the host vehicle V is backward, the overall confidence level included in the overall confidence level signal is used for backward travel shown in FIG. It is adapted to the acceleration suppression condition calculation map Then, the acceleration suppression control start timing is calculated based on the total certainty factor.
- FIG. 22 is a figure which shows the acceleration suppression condition calculation map for the time of reverse. In FIG. 22, as in FIG. 14, the acceleration suppression control start timing is indicated as “suppression control start timing (accelerator opening)” in the “acceleration suppression condition” column.
- the acceleration with respect to the overall certainty factor is compared with the acceleration suppression condition calculation map of the first embodiment described above.
- the acceleration suppression control start timing shown in FIG. 22 is an example, and may be changed according to the specifications of the host vehicle V and the like, similar to the acceleration suppression control start timing shown in FIG.
- the acceleration suppression control amount calculation unit 44 of the present embodiment determines that the traveling direction of the host vehicle V is backward, the overall certainty factor included in the comprehensive certainty factor signal is used for the reverse time shown in FIG. Adapt to the acceleration suppression condition calculation map. Then, an acceleration suppression control amount is calculated based on the total certainty factor. In FIG. 22, as in FIG. 14, the acceleration suppression control amount is indicated as “suppression amount” in the “acceleration suppression condition” column.
- the acceleration suppression with respect to the overall certainty factor is compared with the acceleration suppression condition calculation map of the first embodiment described above. Set a large control amount. Therefore, in the reverse acceleration suppression condition calculation map used by the acceleration suppression control amount calculation unit 44 of the present embodiment, when the traveling direction of the host vehicle V is backward, the traveling direction of the host vehicle V is forward. However, the degree of suppression of the acceleration command value is increased.
- the acceleration suppression control amount is set to the actual accelerator pedal 32 as shown in FIG. Is set to a control amount that is suppressed to the throttle opening of the “medium” level.
- the acceleration suppression control amount shown in FIG. 22 is an example, and may be changed according to the specifications of the host vehicle V and the like, similar to the acceleration suppression control amount shown in FIG.
- the acceleration suppression control start timing is set earlier than when the traveling direction of the host vehicle V is backward, and acceleration is performed. Set a large suppression control amount. For this reason, in this embodiment, when the traveling direction of the host vehicle V is backward, the degree of suppression of the acceleration command value is higher than when the traveling direction of the host vehicle V is forward.
- the acceleration suppression control start timing calculation unit 42 calculates the acceleration suppression control start timing based on the total reliability calculated by the total reliability calculation unit 40, and the acceleration suppression control amount calculation unit 44 calculates an acceleration suppression control amount.
- the acceleration suppression command value calculation unit 10J outputs an acceleration suppression command value signal to the target throttle opening calculation unit 10K.
- the target throttle opening calculation unit 10K outputs a target throttle opening signal to the engine controller 12.
- the parking frame certainty calculation unit 36 calculates the parking frame certainty factor
- the traveling direction of the host vehicle V is forward
- the traveling direction of the host vehicle V is backward.
- the degree of suppression of the acceleration command value is higher than when the traveling direction of the host vehicle V is forward.
- the process of calculating the total certainty factor by the total certainty factor calculation unit 40 when the traveling direction of the host vehicle V is forward, parking is performed more than when the traveling direction of the host vehicle V is backward. The level of frame confidence is made difficult to increase.
- the acceleration suppression control start timing calculation unit 42 calculates the acceleration suppression control start timing, when the traveling direction of the host vehicle V is forward, the traveling direction of the host vehicle V is backward. Rather than raising the level of confidence in the parking frame. For this reason, when the acceleration suppression control operation condition is satisfied, when the traveling direction of the host vehicle V is backward, the degree of suppression of the acceleration command value is higher than when the traveling direction of the host vehicle V is forward.
- the acceleration suppression control amount calculation unit 44 calculates the acceleration suppression control amount
- the traveling direction of the host vehicle V is forward
- the traveling direction of the host vehicle V is backward than when the traveling direction is backward.
- the acceleration suppression control operation condition is satisfied
- the traveling direction of the host vehicle V is backward
- the degree of suppression of the acceleration command value is higher than when the traveling direction of the host vehicle V is forward.
- the shift position sensor 20 and the shift position calculation unit 10E described above correspond to the own vehicle traveling direction detection unit.
- the acceleration command according to the operation amount of the accelerator pedal 32 is compared to when the traveling direction is backward. It is a method of suppressing the value with a low suppression degree.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K move forward when the traveling direction of the host vehicle V is backward.
- the degree of suppression of the acceleration command value is increased compared to the case where
- the acceleration command value is larger than in a backward movement in which the driver is less likely to visually recognize the traveling direction than during the forward traveling. It is possible to reduce the decrease in drivability and reduce the drivability. Further, when the traveling direction of the host vehicle V is a backward movement in which the driver is less likely to visually recognize the traveling direction than when the vehicle is traveling forward, the acceleration command value is larger than when the driver is traveling forward in which the traveling direction is easily visible. It is possible to increase the degree of suppression and increase the acceleration suppression effect of the host vehicle V. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the traveling direction of the host vehicle V is detected.
- the acceleration command value is lower than when the host vehicle V is traveling backward. Suppress with the degree of suppression.
- the traveling direction of the host vehicle V is a forward movement in which the driver can easily recognize the traveling direction
- the acceleration command value is larger than in a backward movement in which the driver is less likely to visually recognize the traveling direction than during the forward traveling. It is possible to reduce the decrease in drivability and reduce the drivability.
- the acceleration command value is larger than when the driver is traveling forward in which the traveling direction is easily visible. It is possible to increase the degree of suppression and increase the acceleration suppression effect of the host vehicle V. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the present invention when the traveling direction of the host vehicle V is forward, the level of the parking frame reliability is less likely to be increased than when the traveling direction of the host vehicle V is backward, and the acceleration command Although the degree of suppression of the value is configured to be low, the present invention is not limited to this. That is, for example, when at least one of the parallelism threshold value, the turning radius threshold value, the first threshold value, and the second threshold value is changed and the traveling direction of the host vehicle V is forward, the traveling direction of the host vehicle V The level of the parking frame approach reliability may be less likely to increase than when the vehicle is moving backward.
- the traveling direction of the host vehicle V when the traveling direction of the host vehicle V is forward, the set travel distance is set longer than when the traveling direction of the host vehicle V is backward, and the level of parking frame reliability is set.
- the level of parking frame reliability is set.
- the traveling direction of the host vehicle V when the traveling direction of the host vehicle V is backward, the process is continued as a line of about 5 [m] obtained by extending a virtual line of about 3 [m].
- the traveling direction of the own vehicle V when the traveling direction of the own vehicle V is forward, the level of the parking frame reliability may be made less likely to be raised than when the traveling direction of the own vehicle V is backward.
- the traveling direction of the host vehicle V is detected using the shift position sensor 20 and the shift position calculation unit 10E described above, but the present invention is not limited to this. That is, for example, the host vehicle V includes a longitudinal acceleration sensor that detects acceleration in the longitudinal direction of the vehicle body (vehicle longitudinal direction), and the traveling direction of the host vehicle V is detected based on the acceleration detected by the longitudinal acceleration sensor. May be.
- the acceleration suppression control start timing and the acceleration suppression control amount are calculated based on the total reliability calculated by the total reliability calculation unit 40, but the present invention is not limited to this. That is, the acceleration suppression control start timing and the acceleration suppression control amount are calculated based on the parking frame reliability calculated by the parking frame reliability calculation unit 36 and whether the traveling direction of the host vehicle V is forward or backward. Also good. In this case, the acceleration suppression control start timing and the acceleration suppression control amount are calculated by adapting the parking frame certainty to, for example, the acceleration suppression condition calculation map shown in FIG. FIG. 23 is a diagram illustrating a modification of the present embodiment.
- the present embodiment a third embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described with reference to the drawings.
- the configuration of the vehicle acceleration suppression device 1 of the present embodiment will be described using FIG. 24 with reference to FIGS. 1 to 23.
- the vehicle acceleration suppression device 1 of the present embodiment is the same as the first embodiment except for the processing performed by the acceleration suppression control content calculation unit 10I, and therefore, except for the processing performed by the acceleration suppression control content calculation unit 10I. The description may be omitted.
- the acceleration suppression apparatus 1 for vehicles of this embodiment WHEREIN: Processes other than the process which the parking frame reliability calculation part 36 and the total reliability calculation part 40 perform among the processes performed by the acceleration suppression control content calculating part 10I are mentioned above. Since this is the same as the first embodiment, the description thereof is omitted.
- the parking frame certainty calculation unit 36 of the present embodiment first receives an input of a steering angle signal, determines whether or not the traveling state of the host vehicle V is a turning state, and The set movement distance is set according to the determination result. Then, based on the set movement distance set according to whether or not the traveling state of the host vehicle V is a turning state, the process proceeds from step S206 until the movement distance of the host vehicle V becomes the set movement distance.
- the process of step S206 performs a process of determining whether or not to collate continuously.
- an operation amount (rotation angle) from the neutral position of the steering wheel 28 included in the steering angle signal is referred to. Further, it is determined whether or not the referred rotation angle exceeds a preset turning state determination threshold value (for example, 90 [°]). And when the referred rotation angle exceeds the turning state determination threshold value, it is determined that the host vehicle V is in a turning state.
- the turning state determination threshold value is not limited to 90 [°], and may be changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example.
- the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels.
- the process of setting the set movement distance according to whether or not the traveling state of the host vehicle V is a turning state is performed with reference to a steering angle signal received from the steering angle calculation unit 10C, for example.
- the set movement distance is set to 2.5 [m], and the traveling state of the host vehicle V is a turning state. If it is determined, the case where the set moving distance is set to 1 [m] will be described.
- the set travel distance is an example, and may be changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example. Further, for example, the vehicle V may be changed according to the traffic regulations of the area (country etc.) where the vehicle V travels.
- step S208 when the traveling state of the host vehicle V is the turning state, the level of the parking frame certainty is “level” compared to when the traveling state of the host vehicle V is not the turning state. It becomes difficult to calculate as “1”.
- the comprehensive reliability calculation part 40 of this embodiment performs the process similar to the parking frame reliability calculation part 36 mentioned above, for example, and determines whether the driving state of the own vehicle V is a turning state. I do.
- the overall certainty calculation unit 40 of the present embodiment receives the parking frame certainty signal and the parking frame approach certainty signal, receives the parking frame certainty factor included in the parking frame certainty signal, and the parking frame approach certainty signal.
- the parking frame approach reliability included in is adapted to the overall reliability calculation map shown in FIG. Then, based on the parking frame certainty factor and the parking frame approach certainty factor, the total certainty factor is calculated.
- FIG. 24 is a diagram showing an overall certainty factor calculation map used in the present embodiment. In FIG. 24, as in FIG. 13, the parking frame certainty factor is indicated as “frame certainty factor”, and the parking frame approach certainty factor is indicated as “entry certainty factor”.
- the comprehensive certainty calculation map used by the comprehensive certainty calculation unit 40 of the present embodiment is different from the comprehensive certainty calculation map used by the comprehensive certainty calculation unit 40 of the first embodiment described above.
- the level of the total certainty level is changed according to the determination result of whether or not it is in a state.
- the total certainty factor when it is determined that the host vehicle V is not in a turning state is “low level in non-turning state” and “high level in non-turning state” in the “entry certainty” column. It shows.
- the total reliability when it is determined that the host vehicle V is in the turning state is “level low in turning state” and “level high in turning state” in the “entry reliability” column. It shows. Further, as shown in FIG.
- the total certainty factor calculation unit 40 of the present embodiment determines the total certainty factor when the host vehicle V is in a turning state, and determines that the host vehicle V is not in a turning state.
- the level is calculated as a level that is equal to or higher than the overall certainty.
- the parking frame certainty factor is “level 2”, and the parking frame approach certainty factor is “high level when not turning”. In this case, as shown in FIG. 24, the total certainty factor is calculated as “low”. On the other hand, when the parking frame certainty factor is “level 2” and the parking frame approach certainty factor is “high level when turning”, as shown in FIG. 24, the total certainty factor is calculated as “high”. . Therefore, in the present embodiment, when the host vehicle V is in a turning state, the total confidence level is easily calculated as a higher level than when the host vehicle V is not in a turning state. Thereby, in this embodiment, when the own vehicle V is in the turning state, the degree of suppression of the acceleration command value is higher than when the own vehicle V is not in the turning state.
- the acceleration suppression command value calculation unit 10J When it is determined that the host vehicle V enters the parking frame L0 and the acceleration suppression control operation condition is satisfied, the acceleration suppression command value calculation unit 10J outputs an acceleration suppression command value signal to the target throttle opening calculation unit 10K. To do. Further, the target throttle opening calculation unit 10K outputs a target throttle opening signal to the engine controller 12.
- the total confidence factor calculation unit 40 calculates the total confidence factor
- the total confidence factor is greater than when the host vehicle V is not in a turning state. It is easy to calculate as a high level.
- the vehicle acceleration suppression method increases the amount of operation of the accelerator pedal 32 when the turning state of the host vehicle V is not detected and when the turning state of the host vehicle V is detected. This is a method of suppressing the corresponding acceleration command value with a low suppression degree.
- the steering angle sensor 18 and the steering angle calculation unit 10C detect whether or not the host vehicle V is in a turning state. In addition to this, when the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K are not in the turning state, Compared with the case where V is in a turning state, the degree of suppression of the acceleration command value is lowered.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K are configured so that when the host vehicle V is in a turning state, The degree of suppression of the acceleration command value is increased compared to the case where the vehicle is not in a turning state.
- acceleration is faster than when the driver intends to accelerate less than when traveling straight. It is possible to reduce the degree of suppression of the command value and reduce the decrease in drivability. Further, when the traveling state of the host vehicle V is a turn where the driver is not intending to accelerate more than when the vehicle is traveling straight, the acceleration command value is greater than when the driver is intending to accelerate. It is possible to increase the degree of suppression and increase the acceleration suppression effect of the host vehicle V. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the acceleration command value is suppressed with a low suppression degree. For this reason, when the traveling state of the host vehicle V is straight traveling, in which the driver often intends to accelerate, acceleration is faster than when the driver intends to accelerate less than when traveling straight. It is possible to reduce the degree of suppression of the command value and reduce the decrease in drivability. Further, when the traveling state of the host vehicle V is a turn where the driver is not intending to accelerate more than when the vehicle is traveling straight, the acceleration command value is greater than when the driver is intending to accelerate.
- the degree of suppression of the acceleration command value is increased.
- the degree of suppression of the acceleration command value is made higher than when the host vehicle V is not in a turning state. It is good also as a structure.
- the parking frame certainty factor or the parking frame approach certainty factor can be easily calculated as a higher level than when the host vehicle V is not in a turning state, and the acceleration command value It is good also as a structure from which the suppression degree becomes high.
- the turning state determination threshold is set to a value (for example, 90 [°]) corresponding to the rotation angle of the steering wheel 28, but the turning state determination threshold is limited to this. is not. That is, the configuration of the host vehicle V includes a yaw rate sensor that detects the yaw rate of the host vehicle V, and the turning state determination threshold is set to a value (for example, 100 [R]) corresponding to the yaw rate of the host vehicle V. It may be set.
- the configuration of the host vehicle V is configured to include a turning angle sensor that detects the turning angle of the steered wheels (for example, the right front wheel WFR and the left front wheel WFL), and the turning state determination threshold value is set to the turning value of the steered wheel. You may set to the value (for example, 6 [degree]) corresponding to a steering angle.
- the acceleration suppression control start timing and the acceleration suppression control amount are calculated based on the total reliability calculated by the total reliability calculation unit 40, but the present invention is not limited to this. That is, the acceleration suppression control start timing and the acceleration suppression control amount may be calculated on the basis of the parking frame reliability calculated by the parking frame reliability calculation unit 36 and whether or not the host vehicle V is in a turning state. . In this case, the acceleration suppression control start timing and the acceleration suppression control amount are calculated by adapting the parking frame certainty to, for example, an acceleration suppression condition calculation map shown in FIG. FIG. 25 is a diagram showing a modification of this embodiment. In the state where the acceleration suppression condition calculation map shown in FIG. 25 is used and the traveling state of the host vehicle V is a turning state, for example, an acceleration suppression condition calculation map similar to that shown in FIG. It is also possible to calculate the acceleration suppression control start timing and the acceleration suppression control amount.
- the present embodiment a fourth embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described with reference to the drawings.
- the configuration of the vehicle acceleration suppression device 1 of the present embodiment will be described using FIG. 26 with reference to FIGS. 1 to 25.
- the vehicle acceleration suppression device 1 of the present embodiment is the same as the first embodiment except for the processing performed by the acceleration suppression control content calculation unit 10I, and therefore, except for the processing performed by the acceleration suppression control content calculation unit 10I. The description may be omitted.
- the acceleration suppression apparatus 1 for vehicles of this embodiment WHEREIN Among the processes performed by the acceleration suppression control content calculating part 10I, processes other than the process which the acceleration suppression operation condition judgment part 34 and the comprehensive reliability calculation part 40 perform are mentioned above. Since this is the same as the first embodiment, the description thereof is omitted.
- the acceleration suppression operation condition determination unit 34 determines in which region the vehicle speed of the host vehicle V is suitable among a plurality of preset threshold vehicle speed regions in the process of step S106 described above. I do. And if the process of step S106 is performed, the process which the acceleration suppression operation condition judgment part 34 of this embodiment performs will transfer to step S108.
- FIG. 26 is a map used for processing performed by the acceleration suppression control content calculation unit 10I of the present embodiment, and is a map showing the relationship between the vehicle speed and the control content.
- the four threshold vehicle speed regions are a first vehicle speed region of 0 [km / h], a second vehicle speed region of 0 [km / h] to 15 [km / h], and exceeds 15 [km / h].
- the third vehicle speed region is 20 [km / h] or less, and the fourth vehicle speed region is over 20 [km / h].
- the acceleration suppression operation condition determination unit 34 of the present embodiment determines that the host vehicle V is in the parking frame based on the threshold vehicle speed region in which the vehicle speed of the host vehicle V determined in step S106 is matched in the process of step S118 described above. Change the conditions for judging entry.
- the condition for determining that the host vehicle V enters the parking frame is a condition for determining whether or not to start the acceleration suppression control, and is indicated as “control start” in the “control content” column.
- the set value of the condition A described above is The process which makes the same value as 1st embodiment mentioned above is performed.
- the set value of the condition A is at least one of the set rudder angle value, the set time, the set angle, and the set distance described above.
- a state where the set values of the conditions (A1 to A3) are the same as those in the first embodiment is indicated by a symbol “ ⁇ ”.
- the set value of the condition A is changed to a value that is less likely to be determined when the host vehicle V enters the parking frame than in the first embodiment. To do. This is performed, for example, by processing such as changing the set time in the condition A1 to a time longer than that in the first embodiment.
- FIG. 26 a state where the set value of the condition A is changed to a value that is less likely to be determined when the host vehicle V enters the parking frame than the first embodiment is indicated as “control start condition is restricted”.
- the acceleration suppression operation condition determination unit 34 of the present embodiment in a state in which the acceleration suppression control is operating, is based on a threshold vehicle speed region in which the vehicle speed of the host vehicle V determined in step S106 is suitable, Change the conditions for continuing control.
- the condition for continuing the acceleration suppression control during operation is indicated as “control continuation” in the “control content” column.
- the process of changing the condition for continuing the acceleration suppression control during operation when the vehicle speed of the host vehicle V is outside the fourth vehicle speed region, the process of continuing the acceleration suppression control during operation is performed.
- a state in which the acceleration suppression control during operation is continued is indicated by a symbol “ ⁇ ”.
- the set value of the condition A is changed to a value that is less likely to be determined when the host vehicle V enters the parking frame than the first embodiment.
- a process for facilitating the termination of the acceleration suppression control during operation is performed.
- a state that facilitates terminating the acceleration suppression control during operation is indicated as “relaxation of control termination condition”.
- the overall certainty calculation unit 40 of the present embodiment receives the input of the vehicle speed calculation value signal, and the vehicle speed of the host vehicle V is suitable for any threshold vehicle speed region as in the processing performed by the acceleration suppression operation condition determination unit 34.
- the process which determines is performed.
- the processing result performed by the acceleration suppression operation condition determination unit 34 may be used.
- the comprehensive reliability calculation part 40 of this embodiment calculates a comprehensive reliability based on a parking frame reliability and a parking frame approach reliability, and also based on the threshold vehicle speed area
- the process of changing the level of the overall certainty factor is shown as “confidence factor” in the “control content” column.
- a state in which the level of the total certainty level is maintained during the acceleration suppression control operation is indicated as “holding the certainty level during control”.
- the level of the total certainty calculated based on the parking frame certainty and the parking frame approach certainty is set. Lowering (for example, lowering by one step) is performed.
- a state in which the level of the overall confidence level is lowered in a state where the acceleration suppression control is not operating is indicated as “lowering the level of confidence level except during control”.
- the level of the total certainty calculated based on the parking frame certainty and the parking frame approach certainty regardless of whether or not the acceleration suppression control is operating. (For example, lowering by one step) is performed.
- a state in which the level of the overall confidence level is lowered regardless of whether or not the acceleration suppression control is operating is indicated as “lowering the level of confidence level uniformly”. Therefore, in this embodiment, the higher the vehicle speed of the host vehicle V, the easier it is to calculate the overall confidence level as a lower level. Thereby, in this embodiment, the acceleration command value is suppressed at a higher suppression degree as the vehicle speed of the host vehicle V is lower.
- the acceleration suppression control start timing calculation unit 42 calculates the acceleration suppression control start timing based on the total reliability calculated by the total reliability calculation unit 40, and the acceleration suppression control amount calculation unit 44 calculates an acceleration suppression control amount.
- the acceleration suppression command value calculation unit 10J outputs an acceleration suppression command value signal to the target throttle opening calculation unit 10K.
- the target throttle opening calculation unit 10K outputs a target throttle opening signal to the engine controller 12.
- the vehicle acceleration suppression method of the present embodiment is a method of suppressing the acceleration command value according to the operation amount of the accelerator pedal 32 with a lower suppression degree as the vehicle speed of the host vehicle V is higher.
- the vehicle speed of the host vehicle V is detected by the wheel speed sensor 16 and the host vehicle vehicle speed calculation unit 10B.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K increase the acceleration command value as the vehicle speed of the host vehicle V increases. Is suppressed with a low degree of suppression.
- the acceleration suppression control start timing calculation unit 42, the acceleration suppression control amount calculation unit 44, the acceleration suppression command value calculation unit 10J, and the target throttle opening calculation unit 10K increase the acceleration command value as the vehicle speed of the host vehicle V decreases. Suppress with the degree of suppression.
- the vehicle speed of the own vehicle V is high and there is a high possibility that the driver does not intend to park the own vehicle V, the vehicle speed of the own vehicle V is low and the driver intends to park the own vehicle V.
- the degree of suppression of the acceleration command value is made lower than when there is a high possibility that the acceleration command value is high. Thereby, it becomes possible to reduce the fall of drivability.
- the vehicle speed of the host vehicle V is low and the driver is likely to intend to park the host vehicle V
- the vehicle speed of the host vehicle V is high and the driver intends to park the host vehicle V.
- the degree of suppression of the acceleration command value is made higher than when there is a high possibility that it is not. Thereby, the acceleration suppression effect of the host vehicle V can be increased. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the acceleration command value is suppressed at a lower suppression degree as the vehicle speed of the host vehicle V is higher. For this reason, when the vehicle speed of the own vehicle V is high and there is a high possibility that the driver does not intend to park the own vehicle V, the vehicle speed of the own vehicle V is low and the driver intends to park the own vehicle V.
- the degree of suppression of the acceleration command value is made lower than when there is a high possibility that the acceleration command value is high. Thereby, it becomes possible to reduce the fall of drivability. Furthermore, when the vehicle speed of the host vehicle V is low and the driver is likely to intend to park the host vehicle V, the vehicle speed of the host vehicle V is high and the driver intends to park the host vehicle V.
- the degree of suppression of the acceleration command value is made higher than when there is a high possibility that it is not. Thereby, the acceleration suppression effect of the host vehicle V can be increased. As a result, it is possible to suppress the drivability of the host vehicle V during parking and to suppress acceleration of the host vehicle V when the accelerator pedal 32 is erroneously operated.
- the higher the vehicle speed of the host vehicle V the easier it is to calculate the overall confidence level as a lower level, and the degree of suppression of the acceleration command value is lower.
- the present invention is not limited to this. Absent. That is, for example, the acceleration suppression control start timing and the acceleration suppression control amount may be changed so that the degree of suppression of the acceleration command value decreases as the vehicle speed of the host vehicle V increases. Further, for example, the higher the vehicle speed of the host vehicle V, the easier it is to calculate the parking frame certainty factor or the parking frame approach certainty factor as a low level, and the degree of suppression of the acceleration command value may be reduced.
- each threshold vehicle speed area is not limited to the speed described above, and may be set / changed according to the specifications of the host vehicle V, such as the braking performance of the host vehicle V, for example.
- the entire contents of the Japanese Patent Application 2012-259210 filed on November 27, 2012 to which the present application claims priority form part of the present disclosure by reference.
Landscapes
- Engineering & Computer Science (AREA)
- Automation & Control Theory (AREA)
- Transportation (AREA)
- Mechanical Engineering (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Mathematical Physics (AREA)
- Combustion & Propulsion (AREA)
- Chemical & Material Sciences (AREA)
- Human Computer Interaction (AREA)
- Control Of Driving Devices And Active Controlling Of Vehicle (AREA)
- Control Of Vehicle Engines Or Engines For Specific Uses (AREA)
- Traffic Control Systems (AREA)
Abstract
Description
特許文献1に記載されている安全装置では、ナビゲーション装置の地図データと、乗り物の現在位置を示す情報に基づき、乗物(自車両)の現在位置が道路(公道等)から外れた位置であることを検出する。これに加え、乗物の走行速度を増加させる方向のアクセル操作があり、さらに、乗物の走行速度が所定値よりも大きいと判断したときは、運転者によるアクセルの操作に拘わらず、スロットルを減速方向に制御する。
しかしながら、上述した判定条件では、乗物が道路から駐車場へ進入すると、車速によってはスロットルの減速方向への制御が作動する。このため、駐車場内において、駐車枠の付近へ移動するまでの走行等における運転性を悪化させてしまうという問題が発生するおそれがある。
本発明は、上記のような問題点に着目してなされたもので、駐車時の運転性低下を抑制するとともに、アクセルの誤操作時における加速を抑制することが可能な、車両用加速抑制装置及び車両用加速抑制方法を提供することを目的とする。
このため、駐車時の運転性低下を抑制するとともに、アクセルの誤操作時における加速を抑制することが可能となる。
(第一実施形態)
以下、本発明の第一実施形態(以下、本実施形態と記載する)について、図面を参照しつつ説明する。
(構成)
まず、図1を用いて、本実施形態の車両用加速抑制装置を備える車両の構成を説明する。
図1は、本実施形態の車両用加速抑制装置を備える車両の構成を示す概念図である。
図1中に示すように、自車両Vは、車輪W(右前輪WFR、左前輪WFL、右後輪WRR、左後輪WRL)と、ブレーキ装置2と、流体圧回路4と、ブレーキコントローラ6を備える。これに加え、自車両Vは、エンジン8と、エンジンコントローラ12を備える。
流体圧回路4は、各ブレーキ装置2に接続する配管を含む回路である。
ブレーキコントローラ6は、上位コントローラである走行制御コントローラ10から入力を受けた制動力指令値に基づき、各ブレーキ装置2で発生する制動力を、流体圧回路4を介して、制動力指令値に応じた値に制御する。すなわち、ブレーキコントローラ6は、減速制御装置を形成する。なお、走行制御コントローラ10に関する説明は、後述する。
したがって、ブレーキ装置2、流体圧回路4及びブレーキコントローラ6は、制動力を発生する制動装置を形成する。
エンジンコントローラ12は、走行制御コントローラ10から入力を受けた目標スロットル開度信号(加速指令値)に基づき、エンジン8で発生するトルク(駆動力)を制御する。すなわち、エンジンコントローラ12は、加速制御装置を形成する。なお、目標スロットル開度信号に関する説明は、後述する。
したがって、エンジン8及びエンジンコントローラ12は、駆動力を発生する駆動装置を形成する。
なお、自車両Vの駆動源は、エンジン8に限定するものではなく、電動モータを用いて形成してもよい。また、自車両Vの駆動源は、エンジン8と電動モータを組み合わせて形成してもよい。
図2は、本実施形態の車両用加速抑制装置1の概略構成を示すブロック図である。
車両用加速抑制装置1は、図1及び図2中に示すように、周囲環境認識センサ14と、車輪速センサ16と、操舵角センサ18と、シフトポジションセンサ20と、ブレーキ操作検出センサ22と、アクセル操作検出センサ24を備える。これに加え、車両用加速抑制装置1は、ナビゲーション装置26と、走行制御コントローラ10を備える。
周囲環境認識センサ14は、自車両Vの周囲の画像を撮像し、撮像した各画像に基づき、複数の撮像方向に対応した個別の画像を含む情報信号(以降の説明では、「個別画像信号」と記載する場合がある)を生成する。そして、生成した個別画像信号を、走行制御コントローラ10へ出力する。
車輪速センサ16は、例えば、車輪速パルスを計測するロータリエンコーダ等のパルス発生器を用いて形成する。
また、車輪速センサ16は、各車輪Wの回転速度を検出し、この検出した回転速度を含む情報信号(以降の説明では、「車輪速信号」と記載する場合がある)を、走行制御コントローラ10に出力する。
また、操舵角センサ18は、操舵操作子であるステアリングホイール28の現在の回転角度(操舵操作量)である現在操舵角を検出する。そして、検出した現在操舵角を含む情報信号(以降の説明では、「現在操舵角信号」と記載する場合がある)を、走行制御コントローラ10に出力する。なお、操向輪の転舵角を含む情報信号を、操舵角を示す情報として検出してもよい。
なお、操舵操作子は、運転者が回転させるステアリングホイール28に限定するものではなく、例えば、運転者が手で傾ける操作を行なうレバーとしてもよい。この場合、中立位置からのレバーの傾斜角度を、現在操舵角信号に相当する情報信号として出力する。
ブレーキ操作検出センサ22は、制動力指示操作子であるブレーキペダル30に対し、その開度を検出する。そして、検出したブレーキペダル30の開度を含む情報信号(以降の説明では、「ブレーキ開度信号」と記載する場合がある)を、走行制御コントローラ10に出力する。
ここで、制動力指示操作子は、自車両Vの運転者が操作可能であり、且つ開度の変化により自車両Vの制動力を指示する構成である。なお、制動力指示操作子は、運転者が足で踏込み操作を行なうブレーキペダル30に限定するものではなく、例えば、運転者が手で操作するレバーとしてもよい。
ここで、駆動力指示操作子は、自車両Vの運転者が操作可能であり、且つ開度の変化により自車両Vの駆動力を指示する構成である。なお、駆動力指示操作子は、運転者が足で踏込み操作を行なうアクセルペダル32に限定するものではなく、例えば、運転者が手で操作するレバーとしてもよい。
ナビゲーション装置26は、GPS(Global Positioning System)受信機、地図データベースと、表示モニタ等を有する情報呈示装置を備え、経路探索及び経路案内等を行う装置である。
また、ナビゲーション装置26は、GPS受信機を用いて取得した自車両Vの現在位置を含む情報信号(以降の説明では、「自車位置信号」と記載する場合がある)を、走行制御コントローラ10に出力する。これに加え、ナビゲーション装置26は、自車両Vが走行する道路の種別や道路幅員等を含む情報信号(以降の説明では、「走行道路情報信号」と記載する場合がある)を、走行制御コントローラ10に出力する。
情報呈示装置は、走行制御コントローラ10からの制御信号に応じて、警報その他の呈示を音声や画像によって出力する。また、情報呈示装置は、例えば、ブザー音や音声により運転者への情報提供を行うスピーカと、画像やテキストの表示により情報提供を行う表示ユニットを備える。また、表示ユニットは、例えば、ナビゲーション装置26の表示モニタを流用してもよい。
また、走行制御コントローラ10は、駐車のための運転支援処理を行う駐車運転支援部を備える。
走行制御コントローラ10の処理のうち駐車運転支援部は、機能的に、図2中に示すように、周囲環境認識情報演算部10A、自車両車速演算部10B、操舵角演算部10C、操舵角速度演算部10Dの処理を備える。これに加え、駐車運転支援部は、機能的に、シフトポジション演算部10E、ブレーキペダル操作情報演算部10F、アクセル操作量演算部10G、アクセル操作速度演算部10H、加速抑制制御内容演算部10Iの処理を備える。さらに、駐車運転支援部は、機能的に、加速抑制指令値演算部10J、目標スロットル開度演算部10Kの処理を備える。これらの機能は、一または二以上のプログラムで構成される。
ここで、俯瞰画像は、例えば、各カメラ(前方カメラ14F、右側方カメラ14SR、左側方カメラ14SL、後方カメラ14R)で撮像した画像を合成して形成する。また、俯瞰画像には、例えば、路面上に表示された駐車枠の線(以降の説明では、「駐車枠線」と記載する場合がある)等の道路標示を示す画像を含む。
自車両車速演算部10Bは、車輪速センサ16から入力を受けた車輪速信号に基づき、車輪Wの回転速度から自車両Vの速度(車速)を演算する。そして、演算した速度を含む情報信号(以降の説明では、「車速演算値信号」と記載する場合がある)を、加速抑制制御内容演算部10Iへ出力する。
操舵角速度演算部10Dは、操舵角センサ18から入力を受けた現在操舵角信号が含む現在操舵角を微分処理することにより、ステアリングホイール28の操舵角速度を演算する。そして、演算した操舵角速度を含む情報信号(以降の説明では、「操舵角速度信号」と記載する場合がある)を、加速抑制制御内容演算部10Iへ出力する。
ブレーキペダル操作情報演算部10Fは、ブレーキ操作検出センサ22から入力を受けたブレーキ開度信号に基づき、踏込み量が「0」である状態を基準とした、ブレーキペダル30の踏込み量を演算する。そして、演算したブレーキペダル30の踏込み量を含む情報信号(以降の説明では、「制動側踏込み量信号」と記載する場合がある)を、加速抑制制御内容演算部10Iへ出力する。
アクセル操作速度演算部10Hは、アクセル操作検出センサ24から入力を受けたアクセル開度信号が含むアクセルペダル32の開度を微分処理することにより、アクセルペダル32の操作速度を演算する。そして、演算したアクセルペダル32の操作速度を含む情報信号(以降の説明では、「アクセル操作速度信号」と記載する場合がある)を、加速抑制指令値演算部10Jへ出力する。
なお、加速抑制制御内容演算部10Iの詳細な構成と、加速抑制制御内容演算部10Iで行なう処理については、後述する。
また、加速抑制指令値演算部10Jは、入力を受けた加速抑制作動条件判断結果信号の内容に応じて、通常の加速制御で用いる指令値である通常加速指令値を演算する。さらに、演算した通常加速指令値を含む情報信号(以降の説明では、「通常加速指令値信号」と記載する場合がある)を、目標スロットル開度演算部10Kへ出力する。
なお、加速抑制指令値演算部10Jで行なう処理については、後述する。
また、目標スロットル開度演算部10Kは、加速抑制指令値が後述する加速抑制制御開始タイミング指令値を含む場合、後述する加速抑制制御開始タイミングに基づいて、目標スロットル開度信号をエンジンコントローラ12へ出力する。
なお、目標スロットル開度演算部10Kで行なう処理については、後述する。
次に、図1及び図2を参照しつつ、図3及び図4を用いて、加速抑制制御内容演算部10Iの詳細な構成について説明する。
図3は、加速抑制制御内容演算部10Iの構成を示すブロック図である。
図3中に示すように、加速抑制制御内容演算部10Iは、加速抑制作動条件判断部34と、駐車枠確信度算出部36と、駐車枠進入確信度算出部38と、総合確信度算出部40を備える。これに加え、加速抑制制御内容演算部10Iは、加速抑制制御開始タイミング演算部42と、加速抑制制御量演算部44を備える。
加速抑制作動条件判断部34は、加速抑制制御を作動させる条件が成立するか否かを判断し、その判断結果を含む情報信号(以降の説明では、「加速抑制作動条件判断結果信号」と記載する場合がある)を、加速抑制指令値演算部10Jへ出力する。ここで、加速抑制制御とは、アクセルペダル32の踏込み量に応じて自車両Vを加速させる加速指令値を、抑制する制御である。
なお、加速抑制作動条件判断部34が加速抑制制御を作動させる条件が成立するか否かを判断する処理については、後述する。
ここで、駐車枠確信度算出部36は、俯瞰画像信号、車速演算値信号、現在シフト位置信号、自車位置信号及び走行道路情報信号が含む各種情報を参照して、駐車枠確信度を算出する。
また、駐車枠確信度算出部36が確信度の算出対象とする駐車枠には、例えば、図4中に示すように、複数のパターンがある。なお、図4は、駐車枠確信度算出部36が駐車枠確信度の算出対象とする駐車枠のパターンを示す図である。
なお、駐車枠確信度算出部36が駐車枠確信度を算出する処理については、後述する。
ここで、駐車枠進入確信度算出部38は、俯瞰画像信号、車速演算値信号、現在シフト位置信号及び操舵角信号が含む各種情報を参照して、駐車枠進入確信度を算出する。
なお、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する処理については、後述する。
総合確信度算出部40は、駐車枠確信度信号及び駐車枠進入確信度信号の入力を受け、駐車枠確信度と駐車枠進入確信度との総合的な確信の度合いを示す総合確信度を算出する。そして、算出した総合確信度を含む情報信号(以降の説明では、「総合確信度信号」と記載する場合がある)を、加速抑制制御開始タイミング演算部42及び加速抑制制御量演算部44へ出力する。
なお、総合確信度算出部40が総合確信度を算出する処理については、後述する。
ここで、加速抑制制御開始タイミング演算部42は、総合確信度信号、制動側踏込み量信号、車速演算値信号、現在シフト位置信号及び操舵角信号が含む各種情報を参照して、加速抑制制御開始タイミングを演算する。
なお、加速抑制制御開始タイミング演算部42が加速抑制制御開始タイミングを演算する処理については、後述する。
ここで、加速抑制制御量演算部44は、総合確信度信号、制動側踏込み量信号、車速演算値信号、現在シフト位置信号及び操舵角信号が含む各種情報を参照して、加速抑制制御量を演算する。
なお、加速抑制制御量演算部44が加速抑制制御量を演算する処理については、後述する。
次に、図1から図4を参照しつつ、図5から図14を用いて、加速抑制制御内容演算部10Iで行なう処理について説明する。
・加速抑制作動条件判断部34が行なう処理
図1から図4を参照しつつ、図5及び図7を用いて、加速抑制作動条件判断部34が加速抑制制御を作動させる条件(以降の説明では、「加速抑制作動条件」と記載する場合がある)が成立するか否かを判断する処理について説明する。
図5は、加速抑制作動条件判断部34が、加速抑制作動条件が成立するか否かを判断する処理を示すフローチャートである。なお、加速抑制作動条件判断部34は、予め設定したサンプリング時間(例えば、10[msec])毎に、以下に説明する処理を行う。
ステップS102では、ステップS100で取得した画像に基づいて、駐車枠の有無を判断する処理(図中に示す「駐車枠有無判断処理」)を行なう。
ここで、駐車枠の有無を判断する処理は、例えば、自車両Vを基準として予め設定した距離や領域(エリア)内に、駐車枠を特定する白線(駐車枠線)等が存在するか否かを判断して行なう。また、ステップS100で取得した画像中から駐車枠線を認識する処理としては、例えば、エッジ検出等、種々の公知の方式を用いる。
図6は、エッジ検出による駐車枠線の認識方法を模式的に説明する模式図である。
図6(a)中に示すように、駐車枠線Lm,Lnを検出する際には、撮像した画像を示す領域において、横方向への走査を行う。画像の走査の際には、例えば、撮像した画像を二値化処理した白黒画像等を用いる。なお、図6(a)は、撮像した画像を示す図である。
駐車枠線は、路面に比べて十分に明るい白色等で示されることから、路面に比べて輝度が高くなる。このため、図6(b)中に示すように、路面から駐車枠線に変化する境界部分では、輝度が急激に高くなるプラスエッジが検出される。なお、図6(b)は、左から右方向への走査を行った場合の画像中の画素の輝度変化を示すグラフであり、図6(c)は、図6(a)と同様、撮像した画像を示す図である。また、図6(b)中では、プラスエッジを符合「E+」で示し、図6(c)中では、プラスエッジを符合「E+」を付した太い実線で示す)
そして、駐車枠線を認識する処理においては、走査方向に対して、プラスエッジ(E+)、マイナスエッジ(E-)の順で、隣接する一対のエッジを検出することにより、駐車枠線が存在すると判断する。
なお、駐車枠の有無を判断する処理としては、駐車枠確信度算出部36が駐車枠確信度を算出する際に行なう処理を用いてもよい。
ステップS102において、駐車枠が有る(図中に示す「Yes」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS104へ移行する。
ステップS104では、自車両車速演算部10Bから入力を受けた車速演算値信号を参照して、自車両Vの車速を取得する処理(図中に示す「自車両車速情報取得処理」)を行う。ステップS104において、自車両Vの車速を取得する処理を行うと、加速抑制作動条件判断部34が行なう処理は、ステップS106へ移行する。
ステップS106では、ステップS104で取得した車速に基づいて、自車両Vの車速が、予め設定した閾値車速未満である条件が成立しているか否かを判断する処理(図中に示す「自車両車速条件判断処理」)を行う。
ステップS106において、自車両Vの車速が閾値車速未満である条件が成立している(図中に示す「Yes」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS108へ移行する。
一方、ステップS106において、自車両Vの車速が閾値車速未満である条件が成立していない(図中に示す「No」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS120へ移行する。
ステップS110では、ステップS108で取得したブレーキペダル30の踏込み量に基づいて、ブレーキペダル30が操作されているか否かを判断する処理(図中に示す「ブレーキペダル操作判断処理」)を行う。
一方、ステップS110において、ブレーキペダル30が操作されている(図中に示す「Yes」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS120へ移行する。
ステップS112では、アクセル操作量演算部10Gから入力を受けた駆動側踏込み量信号を参照して、アクセルペダル32の踏込み量(操作量)の情報を取得する処理(図中に示す「アクセルペダル操作量情報取得処理」)を行う。ステップS112において、アクセルペダル32の踏込み量(操作量)の情報を取得する処理を行うと、加速抑制作動条件判断部34が行なう処理は、ステップS114へ移行する。
なお、本実施形態では、一例として、閾値アクセル操作量を、アクセルペダル32の開度の3[%]に相当する操作量に設定した場合について説明する。また、閾値アクセル操作量は、アクセルペダル32の開度の3[%]に相当する操作量に限定するものではなく、例えば、自車両Vの制動性能等、自車両Vの諸元に応じて変更してもよい。
ステップS114において、アクセルペダル32の踏込み量(操作量)が閾値アクセル操作量以上である条件が成立している(図中に示す「Yes」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS116へ移行する。
ステップS116では、自車両Vが駐車枠へ進入するか否かを判断するための情報を取得する処理(図中に示す「駐車枠進入判断情報取得処理」)を行う。ここで、本実施形態では、一例として、ステアリングホイール28の操舵角と、自車両Vと駐車枠とのなす角度と、自車両Vと駐車枠との距離に基づいて、自車両Vが駐車枠へ進入するか否かを判断する場合を説明する。ステップS116において、自車両Vが駐車枠へ進入するか否かを判断するための情報を取得する処理を行うと、加速抑制作動条件判断部34が行なう処理は、ステップS118へ移行する。
ステップS116では、操舵角演算部10Cから入力を受けた操舵角信号を参照して、ステアリングホイール28の回転角(操舵角)を取得する。これに加え、周囲環境認識情報演算部10Aから入力を受けた俯瞰画像信号が含む自車両Vの周囲の俯瞰画像に基づき、自車両Vと駐車枠L0とのなす角度αと、自車両Vと駐車枠L0との距離Dを取得する。
ここで、角度αは、例えば、図7中に示すように、直線Xと、枠線L1及び駐車枠L0側の線との交角の絶対値とする。なお、図7は、自車両Vと、駐車枠L0と、自車両Vと駐車枠L0との距離Dを説明する図である。
また、距離Dは、例えば、図7中に示すように、自車両Vの前端面の中心点PFと駐車枠L0の入り口L2の中心点PPとの距離とする。ただし、距離Dは、自車両Vの前端面が駐車枠L0の入り口L2を通過した後は、負の値とする。なお、距離Dは、自車両Vの前端面が駐車枠L0の入り口L2を通過した後は、ゼロに設定してもよい。
ここで、距離Dを特定するための自車両V側の位置は、中心点PFに限定するものではなく、例えば、自車両Vに予め設定した位置と、入り口L2の予め設定した位置としてもよい。この場合、距離Dは、自車両Vに予め設定した位置と、入り口L2の予め設定した位置との距離とする。
ステップS118では、ステップS116で取得した情報に基づいて、自車両Vが駐車枠へ進入するか否かを判断する処理(図中に示す「駐車枠進入判断処理」)を行う。
ステップS118において、自車両Vが駐車枠へ進入しない(図中に示す「No」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS120へ移行する。
一方、ステップS118において、自車両Vが駐車枠へ進入する(図中に示す「Yes」)と判断した場合、加速抑制作動条件判断部34が行なう処理は、ステップS122へ移行する。
ステップS118では、例えば、以下に示す三つの条件(A1~A3)を全て満足した場合に、自車両Vが駐車枠へ進入すると判断する。
条件A1.ステップS116で検出した操舵角が予め設定した設定舵角値(例えば、45[deg])以上の値となってから経過した時間が、予め設定した設定時間(例えば、20[sec])以内である。
条件A2.自車両Vと駐車枠L0の角度αが、予め設定した設定角度(例えば、40[deg])以下である。
条件A3.自車両Vと駐車枠L0の距離Dが、予め設定した設定距離(例えば、3[m])以下である。
また、自車両Vが駐車枠へ進入するか否かの判断に用いる処理は、上記のように複数の条件を用いた処理に限定するものではなく、上述した三つの条件のうち一つ以上の条件で判断する処理を用いてもよい。また、自車両Vの車速を用いて、自車両Vが駐車枠へ進入するか否かを判断する処理を用いてもよい。
ステップS120では、加速抑制作動条件判断結果信号を、加速抑制制御作動条件が成立しない判断結果を含む情報信号として生成する処理(図中に示す「加速抑制作動条件非成立」)を行う。ステップS120において、加速抑制制御作動条件が成立しない判断結果を含む加速抑制作動条件判断結果信号を生成する処理を行うと、加速抑制作動条件判断部34が行なう処理は、ステップS124へ移行する。
ステップS124では、ステップS120またはステップS122で生成した加速抑制作動条件判断結果信号を、加速抑制指令値演算部10Jへ出力する処理(図中に示す「加速抑制作動条件判断結果出力」)を行う。ステップS124において、加速抑制作動条件判断結果信号を加速抑制指令値演算部10Jへ出力する処理を行うと、加速抑制作動条件判断部34が行なう処理は、ステップS100の処理へ復帰(RETURN)する。
図1から図7を参照しつつ、図8から図10を用いて、駐車枠確信度算出部36が駐車枠確信度を算出する処理について説明する。
図8は、駐車枠確信度算出部36が駐車枠確信度を算出する処理を示すフローチャートである。なお、駐車枠確信度算出部36は、予め設定したサンプリング時間(例えば、10[msec])毎に、以下に説明する処理を行う。
図8中に示すように、駐車枠確信度算出部36が処理を開始(START)すると、まず、ステップS200において、駐車枠確信度のレベルを最低値(レベル0)として算出(設定)する処理(図中に示す「レベル0」)を行う。ステップS200において、駐車枠確信度をレベル0として算出する処理を行うと、駐車枠確信度算出部36が行なう処理は、ステップS202へ移行する。
ステップS204では、ステップS202で取得した俯瞰画像から、駐車枠確信度を算出するために用いる判定要素を抽出する処理(図中に示す「判定要素抽出」)を行う。ステップS204において、俯瞰画像から判定要素を抽出する処理を行うと、駐車枠確信度算出部36が行なう処理は、ステップS206へ移行する。
条件B1.路面上に標示されている線に破断部分がある場合、その破断部分が、標示されていた線がかすれている部分(例えば、線よりも明瞭度が低く、且つ路面よりも明瞭度が高い部分)である。
条件B2.路面上に標示されている線の幅が、予め設定した設定幅(例えば、10[cm])以上である。なお、設定幅は、10[cm]に限定するものではなく、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
条件B3.路面上に標示されている線の長さが、予め設定した設定標示線長さ(例えば、2.5[m])以上である。なお、設定標示線長さは、2.5[m]に限定するものではなく、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
ステップS206において、ステップS204で抽出した判定要素が、駐車枠線を形成する線の条件に適合していない(図中に示す「No」)と判断した場合、駐車枠確信度算出部36が行なう処理は、ステップS200へ移行する。
一方、ステップS206において、ステップS204で抽出した判定要素が、駐車枠線を形成する線の条件に適合している(図中に示す「Yes」)と判断した場合、駐車枠確信度算出部36が行なう処理は、ステップS208へ移行する。なお、ステップS206で行なう処理は、例えば、周囲環境認識情報演算部10Aから入力を受けた俯瞰画像信号を参照して行なう。
ステップS206では、まず、ステップS204で抽出した判定要素である路面上に標示されている線から、同一画面上に表示されている隣接した二本の線を一つの組として特定(以降の説明では、「ペアリング」と記載する場合がある)する。なお、同一画面上に三本以上の線が表示されている場合は、三本以上の線に対し、それぞれ、隣接した二本の線により、二つ以上の組を特定する。
条件C1.図9(a)中に示すように、ペアリングした二本の線(図中では、符合「La」、符合「Lb」で示す)間の幅WLが、予め設定した設定ペアリング幅(例えば、2.5[m])以下である。なお、設定ペアリング幅は、2.5[m]に限定するものではなく、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
なお、図9(b)中には、基準線(領域PEの垂直方向に延在する線)を、符合「CLc」を付した点線で示し、線Laの中心軸線を、符合「CLa」を付した破線で示し、線Lbの中心軸線を、符合「CLb」を付した破線で示す。また、基準線CLcに対する中心軸線CLaの傾斜角を符号「θa」で示し、基準線CLcに対する中心軸線CLbの傾斜角を符号「θb」で示す。
したがって、|θa-θb|≦3[°]の条件式が成立すると、条件C2を満足することとなる。
条件C4.図9(d)中に示すように、線Laの幅W0と線Lbの幅W1との差の絶対値(|W0-W1|)が、予め設定した設定線幅(例えば、10[cm])以下である。なお、設定線幅は、10[cm]に限定するものではなく、例えば、周囲環境認識センサ14の認識能力等に応じて変更してもよい。
ステップS208では、ステップS206の処理を開始してから自車両Vの移動距離が予め設定した設定移動距離となるまでに、ステップS206の処理が連続して照合するか否かを判断する処理(図中に示す「連続照合適合?」)を行う。なお、設定移動距離は、自車両Vの諸元に応じて、例えば、1~2.5[m]の範囲内に設定する。また、ステップS208で行なう処理は、例えば、周囲環境認識情報演算部10Aから入力を受けた俯瞰画像信号と、自車両車速演算部10Bから入力を受けた車速演算値信号を参照して行なう。
一方、ステップS208において、ステップS206の処理が連続して照合している(図中に示す「Yes」)と判断した場合、駐車枠確信度算出部36が行なう処理は、ステップS212へ移行する。
ここで、ステップS208で行なう処理では、例えば、図10中に示すように、ステップS206の処理が照合された状態と、ステップS206の処理が照合されない状態に応じて、自車両Vの移動距離を仮想的に演算する。なお、図10は、駐車枠確信度算出部36が行なう処理の内容を示す図である。また、図10中には、「照合状態」と記載した領域において、ステップS206の処理が照合された状態を「ON」と示し、ステップS206の処理が照合されない状態を「OFF」と示す。また、図10中には、仮想的に演算した自車両Vの移動距離を、「仮想走行距離」と示す。
なお、本実施形態では、一例として、仮想走行距離が増加する際の傾き(増加ゲイン)を、仮想走行距離が減少する際の傾き(減少ゲイン)よりも大きく設定した場合について説明する。すなわち、「照合状態」が「ON」である状態と「OFF」である状態が同時間であれば、仮想走行距離は増加することとなる。
そして、仮想走行距離が初期値(図中では、「0[m]」と示す)に戻ることなく、設定移動距離に達すると、ステップS206の処理が連続して照合していると判断する。
ステップS212では、ステップS206の処理が連続して照合している線La,Lbに対し、それぞれ、自車両Vを基準として同じ側に位置する端点(近い側の端点、または、遠い側の端点)を検出する。そして、同じ側に位置する端点同士が、幅WLの方向に沿って対向しているか否かを判断する処理(図中に示す「遠近端点対向適合?」)を行う。なお、ステップS212で行なう処理は、例えば、周囲環境認識情報演算部10Aから入力を受けた俯瞰画像信号と、自車両車速演算部10Bから入力を受けた車速演算値信号を参照して行なう。
一方、ステップS212において、同じ側に位置する端点同士が、幅WLの方向に沿って対向している(図中に示す「Yes」)と判断した場合、駐車枠確信度算出部36が行なう処理は、ステップS216へ移行する。
ステップS214では、駐車枠確信度のレベルを最低値(レベル0)よりも二段階上のレベル(レベル2)として算出する処理(図中に示す「レベル2」)を行う。ステップS214において、駐車枠確信度をレベル2として算出する処理を行うと、駐車枠確信度算出部36が行なう処理は終了(END)する。
また、線La,Lbの端点を検出する際には、例えば、図4(n)中に示す上下方向に延在する傾斜した二重線と、左右方向に延在する一本の直線との交点は、端点として処理(認識)しない。これは、端点を検出する際には、撮像した画像を示す領域において、横方向への走査を行うことにより端点を検出するためである。また、例えば、図4(p)中に白枠の四角形で示す領域は、柱等の路上物体を示しているため、この物体の端点も検出しない。
一方、ステップS216において、他方の側に位置する端点同士が、幅WLの方向に沿って対向している(図中に示す「Yes」)と判断した場合、駐車枠確信度算出部36が行なう処理は、ステップS220へ移行する。
ステップS218では、駐車枠確信度のレベルを最低値(レベル0)よりも三段階上のレベル(レベル3)として算出する処理(図中に示す「レベル3」)を行う。ステップS218において、駐車枠確信度をレベル3として算出する処理を行うと、駐車枠確信度算出部36が行なう処理は終了(END)する。
したがって、駐車枠確信度をレベル3として算出する処理では、図4中に示す駐車枠のうち、(d),(e),(j),(k)のパターンに対し、駐車枠確信度を算出することとなる。また、駐車枠確信度をレベル4として算出する処理では、図4中に示す駐車枠のうち、(d),(e),(j),(k)を除くパターンに対し、駐車枠確信度を算出することとなる。
具体的には、例えば、駐車枠の幅が2.6[m]以下であれば、駐車枠確信度は当初算出したレベルを保持するが、駐車枠の幅が2.6[m]を超えている場合には、駐車枠確信度がレベル3以上として算出されないように制限する。これにより、公道上に標示されている両側破線が駐車枠線として検出されにくい構成とする。
図1から図10を参照しつつ、図11及び図12を用いて、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する処理について説明する。
図11は、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する処理を示すフローチャートである。なお、駐車枠進入確信度算出部38は、予め設定したサンプリング時間(例えば、10[msec])毎に、以下に説明する処理を行う。
図11中に示すように、駐車枠進入確信度算出部38が処理を開始(START)すると、まず、ステップS300において、自車両Vの後輪予想軌跡と駐車枠とのずれ量を検出する処理(図中に示す「ずれ量検出」)を行う。ステップS300において、自車両Vの後輪予想軌跡と駐車枠とのずれ量を検出する処理を行うと、駐車枠進入確信度算出部38が行なう処理は、ステップS302へ移行する。なお、本実施形態では、一例として、ステップS300で検出するずれ量の単位を[cm]とした場合について説明する。また、本実施形態では、一例として、駐車枠の幅を2.5[m]とした場合について説明する。
また、自車両Vの後輪予想軌跡TRを算出する際には、自車両Vのうち、右後輪WRRと左後輪WRLとの車幅方向における中心点PRを、自車両Vの基準点として設定する。そして、俯瞰画像のうち前方カメラ14F及び左側方カメラ14SLで撮像した画像と、自車両Vの車速と、ステアリングホイール28の回転角(操舵角)を用いて、中心点PRの仮想移動経路を演算し、後輪予想軌跡TRを算出する。
ここで、ステップS302で検出する平行度は、図12中に示すように、駐車枠L0の中心線Yと直線Xとのなす角度θapとして検出する。
なお、ステップS302では、自車両Vが後退しながら駐車枠L0へ移動する場合、例えば、俯瞰画像のうち後方カメラ14Rで撮像した画像を用いて、直線Xと駐車枠L0の長さ方向との平行度を検出する処理を行う。ここで、自車両Vの移動方向(前進、後退)は、例えば、現在シフト位置信号を参照して検出する。
ステップS306では、ステップS302で検出した平行度(θap)が、予め設定した平行度閾値(例えば、15[°])未満であるか否かを判断する処理(図中に示す「平行度<平行度閾値?」)を行う。
ステップS306において、ステップS302で検出した平行度(θap)が平行度閾値以上である(図中に示す「No」)と判断した場合、駐車枠進入確信度算出部38が行なう処理は、ステップS308へ移行する。
ステップS308では、ステップS304で検出した旋回半径が、予め設定した旋回半径閾値(例えば、100[R])以上であるか否かを判断する処理(図中に示す「旋回半径≧旋回半径閾値?」)を行う。
ステップS308において、ステップS304で検出した旋回半径が旋回半径閾値未満である(図中に示す「No」)と判断した場合、駐車枠進入確信度算出部38が行なう処理は、ステップS312へ移行する。
ステップS310では、ステップS300で検出したずれ量が、予め設定した第一閾値(例えば、75[cm])以上であるか否かを判断する処理(図中に示す「ずれ量≧第一閾値?」)を行う。なお、第一閾値は、75[cm]に限定するものではなく、例えば、自車両Vの諸元に応じて変更してもよい。
ステップS310において、ステップS300で検出したずれ量が第一閾値以上である(図中に示す「Yes」)と判断した場合、駐車枠進入確信度算出部38が行なう処理は、ステップS314へ移行する。
ステップS312では、ステップS300で検出したずれ量が、予め設定した第二閾値(例えば、150[cm])以上であるか否かを判断する処理(図中に示す「ずれ量≧第二閾値?」)を行う。ここで、第二閾値は、上述した第一閾値よりも大きな値とする。なお、第二閾値は、150[cm]に限定するものではなく、例えば、自車両Vの諸元に応じて変更してもよい。
ステップS312において、ステップS300で検出したずれ量が第二閾値以上である(図中に示す「Yes」)と判断した場合、駐車枠進入確信度算出部38が行なう処理は、ステップS318へ移行する。
ステップS314では、駐車枠進入確信度を低いレベルとして算出(設定)する処理(図中に示す「進入確信度=レベル低」)を行う。ステップS314において、駐車枠進入確信度を低いレベルとして算出する処理を行うと、駐車枠進入確信度算出部38が行なう処理は終了(END)する。
ステップS316では、駐車枠進入確信度を高いレベルとして算出する処理(図中に示す「進入確信度=レベル高」)を行う。ステップS316において、駐車枠進入確信度を高いレベルとして算出する処理を行うと、駐車枠進入確信度算出部38が行なう処理は終了(END)する。
以上説明したように、駐車枠進入確信度算出部38は、駐車枠進入確信度を、最低値の「レベル0」、レベル0よりも高いレベルの「レベル低」、レベル低よりも高いレベルの「レベル高」のうち、いずれかのレベルとして算出する処理を行う。
なお、自車両Vの構成が、例えば、運転者に対して駐車枠L0への操舵操作を支援する装置(駐車支援装置)を備える構成である場合、駐車支援装置がON状態であれば、駐車枠進入確信度のレベルが上がりやすくなる構成としてもよい。
駐車枠進入確信度のレベルが上がりやすくなる構成の具体例としては、ステップS318の処理で駐車枠進入確信度を「レベル0」として算出した場合であっても、駐車支援装置がON状態である場合には、駐車枠進入確信度を「レベル低」に補正する構成である。また、例えば、ステップS314の処理で駐車枠進入確信度を「レベル低」として算出した場合であっても、駐車支援装置がON状態である場合には、駐車枠進入確信度を「レベル高」に補正する構成である。なお、駐車枠進入確信度のレベルが上がりやすくなる構成としては、例えば、実際の駐車枠への進入状況に因らず、駐車枠進入確信度を予め設定したレベル(例えば、「レベル高」)として算出する構成としてもよい。
図1から図12を参照しつつ、図13を用いて、総合確信度算出部40が総合確信度を算出する処理について説明する。
総合確信度算出部40は、駐車枠確信度信号及び駐車枠進入確信度信号の入力を受け、駐車枠確信度信号が含む駐車枠確信度と、駐車枠進入確信度信号が含む駐車枠進入確信度を、図13中に示す総合確信度算出マップに適合させる。そして、駐車枠確信度と駐車枠進入確信度に基づき、総合確信度を算出する。
なお、図13は、総合確信度算出マップを示す図である。また、図13中では、駐車枠確信度を「枠確信度」と示し、駐車枠進入確信度を「進入確信度」と示す。また、図13中に示す総合確信度算出マップは、自車両Vの前進走行時に用いるマップである。
総合確信度算出部40が総合確信度を算出する処理の一例として、駐車枠確信度が「レベル3」であり、駐車枠進入確信度が「レベル高」である場合では、図13中に示すように、総合確信度を「高」として算出する。
したがって、本実施形態では、自車両Vの駐車完了後にイグニッションスイッチをオフ状態とし、自車両Vの再発進時にイグニッションスイッチをオン状態とした時点では、直前に算出した総合確信度が記憶されている。このため、自車両Vの再発進時にイグニッションスイッチをオン状態とした時点から、直前に算出した総合確信度に基づく制御を開始することが可能となる。
図1から図13を参照しつつ、図14を用いて、加速抑制制御開始タイミング演算部42が加速抑制制御開始タイミングを演算する処理について説明する。
加速抑制制御開始タイミング演算部42は、総合確信度信号の入力を受け、総合確信度信号が含む総合確信度を、図14中に示す加速抑制条件演算マップに適合させる。そして、総合確信度に基づき、加速抑制制御開始タイミングを演算する。
なお、図14は、加速抑制条件演算マップを示す図である。また、図14中では、「加速抑制条件」の欄において、加速抑制制御開始タイミングを「抑制制御開始タイミング(アクセル開度)」と示す。
なお、図14中に示す加速抑制制御開始タイミングは、一例であり、例えば、自車両Vの制動性能等、自車両Vの諸元に応じて変更してもよい。また、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
図1から図14を参照して、加速抑制制御量演算部44が加速抑制制御量を演算する処理について説明する。
加速抑制制御量演算部44は、総合確信度信号の入力を受け、総合確信度信号が含む総合確信度を、図14中に示す加速抑制条件演算マップに適合させる。そして、総合確信度に基づき、加速抑制制御量を演算する。なお、図14中では、「加速抑制条件」の欄において、加速抑制制御量を「抑制量」と示す。
加速抑制制御量演算部44が行なう処理の一例として、総合確信度が「高」である場合では、図14中に示すように、加速抑制制御量を、実際のアクセルペダル32の開度に対して、「中」レベルのスロットル開度に抑制される制御量に設定する。なお、本実施形態では、一例として、「中」レベルのスロットル開度を、実際のアクセルペダル32の開度が25%に抑制されるスロットル開度とする。同様に、「小」レベルのスロットル開度を、実際のアクセルペダル32の開度が50%に抑制されるスロットル開度とし、「大」レベルのスロットル開度を、実際のアクセルペダル32の開度が10%に抑制されるスロットル開度とする。
また、加速抑制制御量演算部44は、総合確信度を加速抑制条件演算マップに適合させ、警告音を出力する制御の有無を設定する。なお、警告音を出力する場合、例えば、ナビゲーション装置26が備える表示モニタに、加速抑制制御を作動させている内容の文字情報や記号・発光等の視覚情報を表示してもよい。
次に、図1から図14を参照しつつ、図15を用いて、加速抑制指令値演算部10Jで行なう処理について説明する。
図15は、加速抑制指令値演算部10Jが行なう処理を示すフローチャートである。なお、加速抑制指令値演算部10Jは、予め設定したサンプリング時間(例えば、10[msec])毎に、以下に説明する処理を行う。
図15中に示すように、加速抑制指令値演算部10Jが処理を開始(START)すると、まず、ステップS400において、加速抑制制御内容演算部10Iから入力を受けた加速抑制作動条件判断結果信号を参照する。そして、加速抑制作動条件判断結果を取得する処理(図中に示す「加速抑制作動条件判断結果取得処理」)を行う。ステップS400において、加速抑制作動条件判断結果を取得する処理を行うと、加速抑制指令値演算部10Jが行なう処理は、ステップS402へ移行する。
なお、加速抑制指令値を演算するための情報とは、例えば、上述した加速抑制制御開始タイミング信号、加速抑制制御量信号、駆動側踏込み量信号、アクセル操作速度信号が含む情報である。
ステップS404では、ステップS400で取得した加速抑制作動条件判断結果が、加速抑制制御作動条件が成立する判断結果か否かを判断する処理(図中に示す「加速抑制制御作動条件成立?」)を行う。
ステップS404において、加速抑制制御作動条件が成立する判断結果である(図中に示す「Yes」)と判断した場合、加速抑制指令値演算部10Jが行なう処理は、ステップS406へ移行する。
ステップS406では、ステップS402で取得した加速抑制指令値を演算するための情報に基づき、加速抑制制御を行うための加速指令値である加速抑制指令値を演算する処理(図中に示す「加速抑制制御用指令値演算」)を行う。ステップS406において、加速抑制指令値を演算する処理を行うと、加速抑制指令値演算部10Jが行なう処理は、ステップS410に移行する。
ここで、加速抑制指令値を演算する処理では、駆動側踏込み量信号が含むアクセルペダル32の踏込み量と、加速抑制制御量信号が含む加速抑制制御量を参照する。そして、スロットル開度を、実際のアクセルペダル32の開度に対して加速抑制制御量に応じた抑制度合い(図14参照)とする加速抑制制御量指令値を演算する。
そして、加速抑制指令値を演算する処理では、上記のように演算した加速抑制制御量指令値及び加速抑制制御開始タイミング指令値を含む指令値を、加速抑制指令値として演算する。
ステップS408では、加速抑制制御を行なわない駆動力制御、すなわち、通常の加速制御で用いる加速指令値である通常加速指令値を演算する処理(図中に示す「通常加速制御用指令値演算」)を行う。ステップS408において、通常加速指令値を演算する処理を行うと、加速抑制指令値演算部10Jが行なう処理は、ステップS412に移行する。
ステップS410では、ステップS406で演算した加速抑制指令値を含む加速抑制指令値信号を、目標スロットル開度演算部10Kに出力する処理(図中に示す「加速抑制指令値出力」)を行う。ステップS410において、加速抑制指令値信号を出力する処理を行うと、加速抑制指令値演算部10Jが行なう処理は終了(END)する。
ステップS412では、ステップS408で演算した通常加速指令値を含む通常加速指令値信号を、目標スロットル開度演算部10Kに出力する処理(図中に示す「通常加速指令値出力」)を行う。ステップS412において、通常加速指令値信号を出力する処理を行うと、加速抑制指令値演算部10Jが行なう処理は終了(END)する。
次に、図1から図15を参照しつつ、図16を用いて、目標スロットル開度演算部10Kで行なう処理について説明する。
図16は、目標スロットル開度演算部10Kが行なう処理を示すフローチャートである。なお、目標スロットル開度演算部10Kは、予め設定したサンプリング時間(例えば、10[msec])毎に、以下に説明する処理を行う。
図16中に示すように、目標スロットル開度演算部10Kが処理を開始(START)すると、まず、ステップS500において、アクセル操作量演算部10Gから入力を受けた駆動側踏込み量信号を参照する。そして、駆動側踏込み量信号が含むアクセルペダル32の踏込み量(操作量)を取得する処理(図中に示す「アクセル操作量取得処理」)を行う。ステップS500において、アクセルペダル32の踏込み量(操作量)を取得する処理を行うと、目標スロットル開度演算部10Kが行なう処理は、ステップS502へ移行する。
ステップS504では、ステップS500で取得したアクセルペダル32の踏込み量と、ステップS502で取得した指令値に基づき、目標スロットル開度の演算(図中に示す「目標スロットル開度演算」)を行う。ステップS504において、目標スロットル開度を演算すると、目標スロットル開度演算部10Kが行なう処理は、ステップS506へ移行する。
一方、ステップS502で取得した指令値が加速抑制指令値である場合(加速抑制作動条件が成立している場合)は、加速抑制制御量指令値に応じたスロットル開度を、目標スロットル開度として演算する。
目標スロットル開度は、例えば、以下の式(1)を用いて演算する。
θ*=θ1-Δθ … (1)
上式(1)中では、目標スロットル開度を「θ*」で示し、アクセルペダル32の踏込み量に応じたスロットル開度を「θ1」で示し、加速抑制制御量を「Δθ」で示す。
ここで、ステップS506では、ステップS502で取得した指令値が加速抑制指令値である場合は、アクセルペダル32の開度(踏み込み量)が加速抑制制御開始タイミングに応じた開度に達したタイミングで、目標スロットル開度信号を出力する。
次に、図1から図16を参照して、本実施形態の車両用加速抑制装置1を用いて行なう動作の一例を説明する。
以下に記載する動作の一例では、駐車場内を走行する自車両Vが、運転者の選択した駐車枠L0に進入する例を説明する。
駐車場内を走行する自車両Vの車速が、閾値車速である15[km/h]以上の状態では、加速抑制制御作動条件が成立しないため、自車両Vには加速抑制制御が作動することなく、運転者の加速意図を反映した通常の加速制御を行なう。
車速が閾値車速未満となり、駐車枠L0を検出し、さらに、ブレーキペダル30が操作されておらず、アクセルペダル32の踏込み量が閾値アクセル操作量以上であると、自車両Vが駐車枠L0へ進入するか否かの判断を行う。
また、自車両Vの走行中には、駐車枠確信度算出部36が駐車枠確信度を算出し、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する。そして、総合確信度算出部40が、駐車枠確信度及び駐車枠進入確信度に基づく総合確信度を算出する。
そして、自車両Vが駐車枠L0へ進入すると判断し、加速抑制制御作動条件が成立すると判断すると、加速抑制指令値演算部10Jが、加速抑制指令値信号を目標スロットル開度演算部10Kへ出力する。さらに、目標スロットル開度演算部10Kが、目標スロットル開度信号をエンジンコントローラ12へ出力する。
このため、加速抑制制御作動条件が成立した状態で、運転者がアクセルペダル32を操作すると、アクセルペダル32の踏み込み量に応じたスロットル開度を、加速抑制制御量指令値に応じた開度に抑制する。これに加え、アクセルペダル32の踏み込み量に応じたスロットル開度を抑制する開始タイミングを、加速抑制制御開始タイミング指令値に応じたタイミングとする。
以上説明したように、本実施形態では、駐車時において、駐車枠L0への進入を行なう前には駐車場内における運転性低下を抑制することが可能であるとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
例えば、路上において、走行路の脇に縦列駐車用の駐車枠L0が標示されている付近に待機している自車両Vを発進させる状況では、ある程度の加速を許容する必要がある。
また、以下に示す状況下においても、ある程度の加速を許容する必要がある。これは、自車両Vを駐車させる駐車枠L0の両脇(左右の駐車枠)に他車両が存在し、その向かい側(各駐車枠から離れた側)に多少のスペースに自車両Vを前側から進入させる。その後、自車両Vを駐車させる駐車枠L0に自車両Vを後側から進入させて駐車を行う状況である。
また、本実施形態では、駐車枠確信度が低い場合、駐車枠確信度が高い場合よりも、加速抑制制御量を小さく演算する。これにより、以下に示すように、自車両Vの現在位置が公道上ではない位置(例えば、駐車場内)である状況下において、運転性低下の抑制が可能となる。
自車両Vの現在位置が公道上ではない位置である状況下において、例えば、周囲環境認識センサ14で撮像した画像内に線を検出しているが、検出した線を駐車枠線と特定できない場合、駐車枠確信度を低いレベルとして算出する。なお、検出した線を駐車枠線と特定できない場合とは、例えば、周囲環境認識センサ14で撮像した画像内に一本の線を検出し、その端部は検出しているが、検出した一本の線の手前側(自車両Vに近い側)には、線を検出していない場合である。
なお、上述した加速抑制指令値演算部10J、目標スロットル開度演算部10Kは、加速制御部に対応する。
また、上述した周囲環境認識情報演算部10Aは、周囲環境認識部に対応する。
また、上述した加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kは、加速抑制部に対応する。
また、上述したスロットル開度は、加速指令値に対応する。
また、上述したナビゲーション装置26は、自車両現在位置検出部及び自車両走行路種別検出部に対応する。
また、上述したように、本実施形態の車両用加速抑制装置1の動作で実施する車両用加速抑制方法は、総合確信度が低いときは、総合確信度が高いときに比べて、アクセルペダル32の操作量に応じた加速指令値を低い抑制度合いで抑制する方法である。ここで、総合確信度は、駐車枠確信度と駐車枠進入確信度との総合的な確信の度合いを示す。また、駐車枠進入確信度は、自車両Vが駐車枠L0へ進入する確信の度合いを示す。
本実施形態であれば、以下に記載する効果を奏することが可能となる。
(1)駐車枠確信度算出部36が、自車両Vの周囲の俯瞰画像(環境)と自車両Vの車速(走行状態)に基づいて、駐車枠確信度を算出する。これに加え、駐車枠確信度算出部36が算出した駐車枠確信度が低いときは、駐車枠確信度が高いときに比べて、加速指令値の抑制度合いを低くする。すなわち、駐車枠確信度算出部36が算出した駐車枠確信度が高いときは、駐車枠確信度が低いときに比べて、加速指令値の抑制度合いを高くする。
このため、駐車枠確信度が低い状態では、加速指令値の抑制度合いを低くして運転性の低下を少なくすることが可能となり、駐車枠確信度が高い状態では、加速指令値の抑制度合いを高くして自車両Vの加速抑制効果を高くすることが可能となる。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
このため、自車両Vの進行方向に駐車枠L0が存在する確信の度合いに加え、自車両Vが駐車枠L0へ進入する確信の度合いに応じて、加速指令値の抑制度合いを制御することが可能となる。
その結果、上述した効果(1)に加え、さらに、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
その結果、アクセルペダル32の踏み込み量に応じたスロットル開度を抑制する開始タイミングを制御して、加速指令値の抑制度合いを制御することが可能となる。
(4)加速抑制制御量演算部44と、加速抑制指令値演算部10Jと、目標スロットル開度演算部10Kが、加速抑制制御量を減少させて、加速指令値の抑制度合いを低くする。
その結果、アクセルペダル32の踏み込み量に応じたスロットル開度の抑制量を制御して、加速指令値の抑制度合いを制御することが可能となる。
このため、駐車枠確信度が低い状態では、加速指令値の抑制度合いを低くして運転性の低下を少なくすることが可能となり、駐車枠確信度が高い状態では、加速指令値の抑制度合いを高くして自車両Vの加速抑制効果を高くすることが可能となる。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
このため、自車両Vの進行方向に駐車枠L0が存在する確信の度合いに加え、自車両Vが駐車枠L0へ進入する確信の度合いに応じて、加速指令値の抑制度合いを制御することが可能となる。
その結果、上述した効果(5)に加え、さらに、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
(1)本実施形態では、総合確信度算出部40が算出した総合確信度に基づいて、加速抑制制御開始タイミングと加速抑制制御量を演算したが、これに限定するものではない。すなわち、駐車枠確信度算出部36が算出した駐車枠確信度のみに基づいて、加速抑制制御開始タイミングと加速抑制制御量を演算してもよい。この場合、加速抑制制御開始タイミングと加速抑制制御量は、駐車枠確信度を、例えば、図17中に示す加速抑制条件演算マップに適合させて演算する。なお、図17は、本実施形態の変形例を示す図である。
この場合、例えば、自車位置信号及び走行道路情報信号が含む情報に基づき、自車両Vの現在位置が公道上であることを検出すると、自車両Vの周囲に駐車枠L0が存在しないと判断し、駐車枠確信度を「レベル0」として算出する。
これにより、例えば、公道上で道路端に配置された駐車枠等、加速抑制制御の作動が好ましくない駐車枠へ自車両Vが進入する際に、自車両Vの運転性低下を抑制することが可能となる。
なお、駐車枠の検知を行われやすくする方法としては、例えば、実際の駐車枠の検知状況に因らず、駐車枠確信度を予め設定したレベル(例えば、「レベル4」)として検知されているとする方法を用いてもよい。
この場合、例えば、算出した駐車枠確信度及び駐車枠進入確信度に加え、条件Bを満足した際に検出した線Lの本数を、図18中に示す総合確信度算出マップに適合させる。そして、駐車枠確信度及び駐車枠進入確信度と、条件Bを満足した際に検出した線Lの種類に基づき、総合確信度を算出する。なお、図18は、本実施形態の変形例で用いる総合確信度算出マップを示す図である。また、図18中では、図13中と同様、駐車枠確信度を「枠確信度」と示し、駐車枠進入確信度を「進入確信度」と示す。
具体的には、駐車枠進入確信度が「レベル低」であり、駐車枠確信度を「レベル1」として算出した場合、条件Bを満足した際に検出した線Lの種類が単線である場合には、「レベル0」の場合と同様、加速抑制制御を行なわない総合確信度として算出する。また、駐車枠進入確信度が「レベル低」であり、駐車枠確信度を「レベル1」として算出した場合、条件Bを満足した際に検出した線Lの種類が二重線である場合には、総合確信度を「極低」として算出する。
ここで、図18中に示す総合確信度算出マップを用いて総合確信度を算出した場合、例えば、算出した総合確信度を、図19中に示す加速抑制条件演算マップに適合させて、加速抑制制御開始タイミングを演算する。なお、図19は、本実施形態の変形例で用いる加速抑制条件演算マップを示す図である。また、図19中では、図14中と同様、「加速抑制条件」の欄において、加速抑制制御開始タイミングを「抑制制御開始タイミング(アクセル開度)」と示す。
一方、総合確信度が「極高」である場合、加速抑制制御開始タイミングを、アクセルペダル32の開度が増加して「50%」に達した時点で時間の計測を開始する。これに加え、アクセルペダル32の開度が「50%」以上となっている計測時間が「0.65[sec]」に達した時点を、加速抑制制御開始タイミングとして設定する。すなわち、総合確信度が「極高」である場合には、アクセルペダル32の開度が「50%」以上となっている計測時間が「0.65[sec]」に達した時点から、加速抑制制御を開始する。
ここで、図19中に示す加速抑制条件演算マップを用いて、加速抑制制御開始タイミングを演算した場合の動作例を説明する。
図19中に示す加速抑制条件演算マップを用いた場合、総合確信度に基づく加速抑制制御開始タイミングと保持時間との関係は、図20中に示す関係となる。なお、図20は、加速抑制制御開始タイミングと保持時間との関係を示す図である。また、図20中では、加速抑制制御開始タイミングを、横軸に「アクセル開度[%]」と示し、保持時間を、縦軸に「保持時間[sec]」と示す。
しかしながら、自車両Vの走行中に周囲環境認識センサ14で撮像した画像が変化した場合には、条件Bを満足した際に検出した線Lの種類が変化する場合がある。
この場合、条件Bを満足した際に検出した線Lの種類が単線から二重線に変化した時点で、総合確信度が「極低」から「極高」に変化する。
条件Bを満足した際に検出した線Lの種類が単線であった時点では、図20中に示す時点PLを、加速抑制制御開始タイミングとして設定しており、アクセル開度が80%に達するまでは、保持時間の計測を開始しない。
しかしながら、総合確信度が「極低」から「極高」に変化すると、既にアクセル開度が50%に達していても、総合確信度が「極低」から「極高」に変化した時点から保持時間の計測を開始することとなる。そして、図20中において、計測時間とアクセル開度との関係が制御閾値を連続的に示す線と重なった時点SPから、加速抑制制御を開始することとなる。なお、図20中には、時間の経過に応じたアクセル開度の変化を、破線で示す。
このため、例えば、タワーパーキング等、複数の駐車枠が配列された構成の駐車場を走行する自車両Vが、下層階の駐車場から上層階の駐車場へ移動する際に登り勾配の坂を走行する状況において、運転性低下を抑制することが可能となる。これは、例えば、登り勾配の坂を走行する前に直進走行から旋回走行に移行して車速が低下し、条件Bを満足した際に検出した線Lの種類が単線から二重線に変化して、総合確信度が「極低」から「極高」に変化する状況に適用される。
この場合、駐車枠進入確信度が「レベル低」から「レベル高」に変化した時点で、総合確信度が「極低」から「極高」に変化する。そして、条件Bを満足した際に検出した線Lの種類が単線から二重線に変化した場合と同様、総合確信度が当初から「極高」として算出されていた場合と比較して、加速抑制制御を開始する時間が遅れることとなる。
このため、例えば、交差点を左折した自車両Vが、左折後に、既に駐車している車両である他車両を追い越してから、道路端に配置された駐車枠に進入して駐車する状況において、運転性低下を抑制することが可能となる。これは、例えば、交差点を左折した自車両Vが、他車両を右側から追い越した後、道路端へ向けて左側へ移動する際に、駐車枠進入確信度が「レベル低」から「レベル高」に変化して、総合確信度が「極低」から「極高」に変化する状況に適用される。
(8)本実施形態では、駐車枠確信度を、最低値であるレベル0と、最低値よりも複数段階上のレベル(レベル1~4)として算出したが、駐車枠確信度の段階は、これに限定するものではない。すなわち、駐車枠確信度を、最低値であるレベル(例えば、「レベル0」)と、最低値よりも上のレベル(例えば、「レベル100」)との二段階のみとして算出してもよい。
この場合、例えば、駐車枠確信度及び駐車枠進入確信度を最低値であるレベルとして算出すると、総合確信度を、最低値であるレベルとして算出する。また、例えば、駐車枠確信度及び駐車枠進入確信度を最低値よりも高いレベルとして算出すると、総合確信度を、最低値よりも高いレベルとして算出する。
以下、本発明の第二実施形態(以下、「本実施形態」と記載する)について、図面を参照しつつ説明する。
(構成)
まず、図1から図20を参照しつつ、図21及び図22を用いて、本実施形態の車両用加速抑制装置1の構成を説明する。
本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理を除き、上述した第一実施形態と同様であるため、加速抑制制御内容演算部10Iで行なう処理以外については、その説明を省略する場合がある。
また、本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理のうち、加速抑制作動条件判断部34と駐車枠進入確信度算出部38が行なう処理以外の処理が、上述した第一実施形態と異なる。このため、以降の説明では、上述した第一実施形態と同様の処理については、記載を省略する場合がある。
ここで、自車両Vの進行方向に応じて設定移動距離を設定する処理は、例えば、シフトポジション演算部10Eから入力を受けた現在シフト位置信号を参照して行なう。
また、本実施形態では、一例として、自車両Vの進行方向が前進であると判定すると、設定移動距離を2.5[m]に設定し、自車両Vの進行方向が後退であると判定すると、設定移動距離を1[m]に設定する場合について説明する。
なお、上記の設定移動距離は、一例であり、例えば、自車両Vの制動性能等、自車両Vの諸元に応じて変更してもよい。また、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
また、本実施形態の駐車枠確信度算出部36は、上述したステップS212の処理において、まず、自車両Vの進行方向が前進であるか後退であるかを判定する。
そして、自車両Vの進行方向が前進である場合は、上述した第一実施形態と同様、同じ側に位置する端点同士が、幅WLの方向に沿って対向していると判断した場合、駐車枠確信度算出部36が行なう処理をステップS216へ移行させる。
したがって、本実施形態では、ステップS212の処理において、自車両Vの進行方向が前進である場合、自車両Vの進行方向が後退である場合よりも、駐車枠確信度のレベルが「レベル3」として算出されにくくなる。
また、本実施形態の総合確信度算出部40は、駐車枠確信度信号及び駐車枠進入確信度信号の入力を受け、駐車枠確信度信号が含む駐車枠確信度と、駐車枠進入確信度信号が含む駐車枠進入確信度を、図21中に示す総合確信度算出マップに適合させる。そして、駐車枠確信度と駐車枠進入確信度に基づき、総合確信度を算出する。
ここで、本実施形態の総合確信度算出部40が用いる総合確信度算出マップは、上述した第一実施形態の総合確信度算出部40が用いる総合確信度算出マップと異なり、自車両Vの進行方向の判定結果に応じて、総合確信度のレベルを変更する。なお、図21中では、自車両Vの進行方向が前進であると判定した場合の総合確信度を、「進入確信度」欄において、「前進時レベル低」及び「前進時レベル高」と示す。これに加え、図21中では、自車両Vの進行方向が後退であると判定した場合の総合確信度を、「進入確信度」欄において、「後退時レベル低」及び「後退時レベル高」と示す。
本実施形態の総合確信度算出部40が総合確信度を算出する処理の一例として、駐車枠確信度が「レベル2」であり、駐車枠進入確信度が「前進時レベル高」である場合では、図21中に示すように、総合確信度を「低」として算出する。一方、駐車枠確信度が「レベル2」であり、駐車枠進入確信度が「後退時レベル高」である場合では、図21中に示すように、総合確信度を「高」として算出する。
また、本実施形態の総合確信度算出部40が総合確信度を算出する処理の一例として、自車両Vの進行方向が前進であっても、既に駐車中とみなし、後退時と同様の算出を行うことで、前進の際に駐車枠確信度のレベルを上がりやすくする処理を行ってもよい。この処理は、自車両Vの前進中に駐車枠確信度が「レベル1」として算出された後に自車両Vが後退し、所定の距離(例えば、2.5[m])以内を後退中に、再度、前進した場合に適用する。
また、本実施形態の加速抑制制御開始タイミング演算部42は、自車両Vの進行方向が後退であると判定した場合、総合確信度信号が含む総合確信度を、図22中に示す後退時用の加速抑制条件演算マップに適合させる。そして、総合確信度に基づき、加速抑制制御開始タイミングを演算する。
なお、図22は、後退時用の加速抑制条件演算マップを示す図である。また、図22中では、図14中と同様、「加速抑制条件」の欄において、加速抑制制御開始タイミングを「抑制制御開始タイミング(アクセル開度)」と示す。
本実施形態の加速抑制制御開始タイミング演算部42が行なう処理の一例として、総合確信度が「低」である場合では、図22中に示すように、加速抑制制御開始タイミングを、アクセルペダル32の開度が増加して「50%」に達したタイミングに設定する。なお、図22中に示す加速抑制制御開始タイミングは、一例であり、図14中に示す加速抑制制御開始タイミングと同様、自車両Vの諸元等に応じて変更してもよい。
ここで、本実施形態の加速抑制制御量演算部44が用いる後退時用の加速抑制条件演算マップでは、上述した第一実施形態の加速抑制条件演算マップと比較して、総合確信度に対する加速抑制制御量を大きめに設定する。したがって、本実施形態の加速抑制制御量演算部44が用いる後退時用の加速抑制条件演算マップでは、自車両Vの進行方向が後退である場合、自車両Vの進行方向が前進である場合よりも、加速指令値の抑制度合いが高くなる。
以上説明したように、本実施形態では、自車両Vの進行方向が前進である場合、自車両Vの進行方向が後退である場合よりも、加速抑制制御開始タイミングを早めに設定するとともに、加速抑制制御量を大きめに設定する。このため、本実施形態では、自車両Vの進行方向が後退である場合、自車両Vの進行方向が前進である場合よりも、加速指令値の抑制度合いが高くなる。
次に、図1から図22を参照して、本実施形態の車両用加速抑制装置1を用いて行なう動作の一例を説明する。なお、上述した第一実施形態と同様の動作等については、説明を省略する場合がある。
以下に記載する動作の一例では、上述した第一実施形態と同様、駐車場内を走行する自車両Vが、運転者の選択した駐車枠L0に進入する例を説明する。
自車両Vの走行中には、駐車枠確信度算出部36が駐車枠確信度を算出し、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する。そして、総合確信度算出部40が、駐車枠確信度及び駐車枠進入確信度に基づく総合確信度を算出する。
そして、自車両Vが駐車枠L0へ進入すると判断し、加速抑制制御作動条件が成立すると判断すると、加速抑制指令値演算部10Jが、加速抑制指令値信号を目標スロットル開度演算部10Kへ出力する。さらに、目標スロットル開度演算部10Kが、目標スロットル開度信号をエンジンコントローラ12へ出力する。
このため、加速抑制制御作動条件が成立した状態では、自車両Vの進行方向が後退である場合、自車両Vの進行方向が前進である場合よりも、加速指令値の抑制度合いが高くなる。
また、本実施形態では、総合確信度算出部40が総合確信度を算出する処理において、自車両Vの進行方向が前進である場合、自車両Vの進行方向が後退である場合よりも、駐車枠確信度のレベルを上がりにくくしている。
また、本実施形態では、加速抑制制御開始タイミング演算部42が加速抑制制御開始タイミングを演算する処理において、自車両Vの進行方向が前進である場合、自車両Vの進行方向が後退である場合よりも、駐車枠確信度のレベルを上がりにくくしている。
このため、加速抑制制御作動条件が成立した状態では、自車両Vの進行方向が後退である場合、自車両Vの進行方向が前進である場合よりも、加速指令値の抑制度合いが高くなる。
このため、加速抑制制御作動条件が成立した状態では、自車両Vの進行方向が後退である場合、自車両Vの進行方向が前進である場合よりも、加速指令値の抑制度合いが高くなる。
なお、上述したシフトポジションセンサ20及びシフトポジション演算部10Eは、自車両進行方向検出部に対応する。
また、上述したように、本実施形態の車両用加速抑制方法は、自車両Vの進行方向が前進である場合は、後退である場合に比べて、アクセルペダル32の操作量に応じた加速指令値を低い抑制度合いで抑制する方法である。
以下、本実施形態の効果を記載する。
本実施形態では、上述した第一実施形態の効果に加え、さらに、以下に記載する効果を奏することが可能となる。
(1)シフトポジションセンサ20及びシフトポジション演算部10Eにより、自車両の走行状態を検出する。これに加え、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kが、自車両Vの進行方向が前進である場合は、後退である場合に比べて、加速指令値の抑制度合いを低くする。すなわち、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kは、自車両Vの進行方向が後退である場合は、前進である場合に比べて、加速指令値の抑制度合いを高くする。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
このため、自車両Vの進行方向が、運転者が進行方向を視認しやすい前進である場合には、前進時よりも運転者が進行方向を視認しにくい後退である場合よりも、加速指令値の抑制度合いを低くして、運転性の低下を少なくすることが可能となる。さらに、自車両Vの進行方向が、前進時よりも運転者が進行方向を視認しにくい後退である場合には、運転者が進行方向を視認しやすい前進である場合よりも、加速指令値の抑制度合いを高くして、自車両Vの加速抑制効果を高くすることが可能となる。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
(1)本実施形態では、自車両Vの進行方向が前進である場合には、自車両Vの進行方向が後退である場合よりも、駐車枠確信度のレベルを上がりにくくして、加速指令値の抑制度合いが低くなる構成としているが、これに限定するものではない。すなわち、例えば、平行度閾値、旋回半径閾値、第一閾値及び第二閾値のうち少なくとも一つの設定を変更して、自車両Vの進行方向が前進である場合には、自車両Vの進行方向が後退である場合よりも、駐車枠進入確信度のレベルを上がりにくくしてもよい。これにより、自車両Vの進行方向が前進である場合には、自車両Vの進行方向が後退である場合よりも、駐車枠進入確信度のレベルを上がりにくくして、加速指令値の抑制度合いが低くなる構成としてもよい。
以下、本発明の第三実施形態(以下、「本実施形態」と記載する)について、図面を参照しつつ説明する。
(構成)
まず、図1から図23を参照しつつ、図24を用いて、本実施形態の車両用加速抑制装置1の構成を説明する。
本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理を除き、上述した第一実施形態と同様であるため、加速抑制制御内容演算部10Iで行なう処理以外については、その説明を省略する場合がある。
また、本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理のうち、駐車枠確信度算出部36と総合確信度算出部40が行なう処理以外の処理は、上述した第一実施形態と同様であるため、その説明を省略する。
なお、旋回状態判断用閾値は、90[°]に限定するものではなく、例えば、自車両Vの制動性能等、自車両Vの諸元に応じて変更してもよい。また、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
ここで、自車両Vの走行状態が旋回状態であるか否かに応じて設定移動距離を設定する処理は、例えば、操舵角演算部10Cから入力を受けた操舵角信号を参照して行なう。
なお、上記の設定移動距離は、一例であり、例えば、自車両Vの制動性能等、自車両Vの諸元に応じて変更してもよい。また、例えば、自車両Vが走行する地域(国等)の交通法規等に応じて変更してもよい。
したがって、本実施形態では、ステップS208の処理において、自車両Vの走行状態が旋回状態である場合、自車両Vの走行状態が旋回状態ではない場合よりも、駐車枠確信度のレベルが「レベル1」として算出されにくくなる。
また、本実施形態の総合確信度算出部40は、駐車枠確信度信号及び駐車枠進入確信度信号の入力を受け、駐車枠確信度信号が含む駐車枠確信度と、駐車枠進入確信度信号が含む駐車枠進入確信度を、図24中に示す総合確信度算出マップに適合させる。そして、駐車枠確信度と駐車枠進入確信度に基づき、総合確信度を算出する。
なお、図24は、本実施形態で用いる総合確信度算出マップを示す図である。また、図24中では、図13中と同様、駐車枠確信度を「枠確信度」と示し、駐車枠進入確信度を「進入確信度」と示す。
また、本実施形態の総合確信度算出部40は、図24中に示すように、自車両Vが旋回状態であると判断した場合の総合確信度を、自車両Vが旋回状態ではないと判断した場合の総合確信度以上のレベルとして算出する。
したがって、本実施形態では、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、総合確信度が高いレベルとして算出されやすくなる。これにより、本実施形態では、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、加速指令値の抑制度合いが高くなる。
次に、図1から図24を参照して、本実施形態の車両用加速抑制装置1を用いて行なう動作の一例を説明する。なお、上述した第一実施形態と同様の動作等については、説明を省略する場合がある。
以下に記載する動作の一例では、上述した第一実施形態と同様、駐車場内を走行する自車両Vが、運転者の選択した駐車枠L0に進入する例を説明する。
自車両Vの走行中には、駐車枠確信度算出部36が駐車枠確信度を算出し、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する。そして、総合確信度算出部40が、駐車枠確信度及び駐車枠進入確信度に基づく総合確信度を算出する。
さらに、自車両Vの走行中には、総合確信度算出部40が算出した総合確信度に基づき、加速抑制制御開始タイミング演算部42が加速抑制制御開始タイミングを演算し、加速抑制制御量演算部44が加速抑制制御量を演算する。
ここで、本実施形態では、総合確信度算出部40が総合確信度を算出する処理において、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、総合確信度を高いレベルとして算出されやすくしている。
なお、上述した操舵角センサ18及び操舵角演算部10Cは、自車両旋回状態検出部に対応する。
また、上述したように、本実施形態の車両用加速抑制方法は、自車両Vの旋回状態を検出しない場合、自車両Vの旋回状態を検出した場合に比べて、アクセルペダル32の操作量に応じた加速指令値を低い抑制度合いで抑制する方法である。
以下、本実施形態の効果を記載する。
本実施形態では、上述した第一実施形態の効果に加え、さらに、以下に記載する効果を奏することが可能となる。
(1)操舵角センサ18及び操舵角演算部10Cにより、自車両Vが旋回状態であるか否かを検出する。これに加え、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kが、自車両Vが旋回状態ではない場合、自車両Vが旋回状態である場合に比べて、加速指令値の抑制度合いを低くする。すなわち、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kは、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合に比べて、加速指令値の抑制度合いを高くする。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
このため、自車両Vの走行状態が、運転者が加速を意図する場合が多い直進である場合には、直進時よりも運転者が加速を意図する場合が少ない旋回である場合よりも、加速指令値の抑制度合いを低くして、運転性の低下を少なくすることが可能となる。さらに、自車両Vの走行状態が、直進時よりも運転者が加速を意図する場合が少ない旋回である場合には、運転者が加速を意図する場合が多い直進時よりも、加速指令値の抑制度合いを高くして、自車両Vの加速抑制効果を高くすることが可能となる。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
(1)本実施形態では、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、総合確信度を高いレベルとして算出されやすくして、加速指令値の抑制度合いが高くなる構成としているが、これに限定するものではない。すなわち、例えば、加速抑制制御開始タイミングや加速抑制制御量を変化させて、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、加速指令値の抑制度合いを高くする構成としてもよい。また、例えば、自車両Vが旋回状態である場合、自車両Vが旋回状態ではない場合よりも、駐車枠確信度や駐車枠進入確信度を高いレベルとして算出されやすくして、加速指令値の抑制度合いが高くなる構成としてもよい。
また、図25中に示す加速抑制条件演算マップを用いた状態で、自車両Vの走行状態が旋回状態である場合には、例えば、図22中に示すものと同様の加速抑制条件演算マップを用いて、加速抑制制御開始タイミングと加速抑制制御量を演算してもよい。
以下、本発明の第四実施形態(以下、「本実施形態」と記載する)について、図面を参照しつつ説明する。
(構成)
まず、図1から図25を参照しつつ、図26を用いて、本実施形態の車両用加速抑制装置1の構成を説明する。
本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理を除き、上述した第一実施形態と同様であるため、加速抑制制御内容演算部10Iで行なう処理以外については、その説明を省略する場合がある。
また、本実施形態の車両用加速抑制装置1は、加速抑制制御内容演算部10Iで行なう処理のうち、加速抑制作動条件判断部34と総合確信度算出部40が行なう処理以外の処理は、上述した第一実施形態と同様であるため、その説明を省略する。
なお、本実施形態では、一例として、図26中に示すように、複数の閾値車速領域として、四つの領域を設定した場合について説明する。また、図26は、本実施形態の加速抑制制御内容演算部10Iで行なう処理に用いるマップであり、車速と制御内容との関連を示すマップである。
次に、本実施形態の加速抑制作動条件判断部34は、上述したステップS118の処理において、ステップS106で判定した自車両Vの車速が適合する閾値車速領域に基づき、自車両Vが駐車枠へ進入すると判断する条件を変更する。なお、図26中では、自車両Vが駐車枠へ進入すると判断する条件を、加速抑制制御を開始するか否かの条件とし、「制御内容」欄に「制御開始」として示す。
一方、自車両Vの車速が第三車速領域または第四車速領域である場合、条件Aの設定値を、第一実施形態よりも、自車両Vが駐車枠へ進入すると判断されにくい値に変更する。これは、例えば、条件A1における設定時間を、第一実施形態よりも長い時間に変更する等の処理によって行なう。なお、図26中では、条件Aの設定値を第一実施形態よりも自車両Vが駐車枠へ進入すると判断されにくい値に変更する状態を、「制御開始条件を規制」と示す。
作動中の加速抑制制御を継続させる条件を変更する処理の具体例としては、自車両Vの車速が第四車速領域以外である場合、作動中の加速抑制制御を継続させる処理を行う。なお、図26中では、作動中の加速抑制制御を継続させる状態を、符合「○」で示す。
一方、自車両Vの車速が第四車速領域である場合、例えば、条件Aの設定値を、第一実施形態よりも、自車両Vが駐車枠へ進入すると判断されにくい値に変更して、作動中の加速抑制制御を終了させやすくする処理を行う。なお、図26中では、作動中の加速抑制制御を終了させやすくする状態を、「制御終了条件を緩和」と示す。
そして、本実施形態の総合確信度算出部40は、駐車枠確信度と駐車枠進入確信度に基づいて総合確信度を算出し、さらに、自車両Vの車速が適合する閾値車速領域に基づき、総合確信度のレベルを変更する処理を行う。なお、図26中では、総合確信度のレベルを変更する処理を、「制御内容」欄に「確信度」として示す。
一方、自車両Vの車速が第三車速領域である場合、加速抑制制御が作動中であれば、駐車枠確信度と駐車枠進入確信度に基づいて算出した総合確信度のレベルを保持する処理を行う。なお、図26中では、加速抑制制御の作動中に総合確信度のレベルを保持する状態を、「制御中は確信度を保持」と示す。
また、自車両Vの車速が第三車速領域である場合、加速抑制制御が作動していない状態であれば、駐車枠確信度と駐車枠進入確信度に基づいて算出した総合確信度のレベルを下げる(例えば、一段階下げる)処理を行う。なお、図26中では、加速抑制制御が作動していない状態で総合確信度のレベルを下げる状態を、「制御中以外は確信度のレベルを下げる」と示す。
したがって、本実施形態では、自車両Vの車速が高いほど、総合確信度が低いレベルとして算出されやすくなる。これにより、本実施形態では、自車両Vの車速が低いほど、加速指令値を高い抑制度合いで抑制する。
次に、図1から図26を参照して、本実施形態の車両用加速抑制装置1を用いて行なう動作の一例を説明する。なお、上述した第一実施形態と同様の動作等については、説明を省略する場合がある。
以下に記載する動作の一例では、上述した第一実施形態と同様、駐車場内を走行する自車両Vが、運転者の選択した駐車枠L0に進入する例を説明する。
自車両Vの走行中には、駐車枠確信度算出部36が駐車枠確信度を算出し、駐車枠進入確信度算出部38が駐車枠進入確信度を算出する。そして、総合確信度算出部40が、駐車枠確信度及び駐車枠進入確信度に基づく総合確信度を算出する。
そして、自車両Vが駐車枠L0へ進入すると判断し、加速抑制制御作動条件が成立すると判断すると、加速抑制指令値演算部10Jが、加速抑制指令値信号を目標スロットル開度演算部10Kへ出力する。さらに、目標スロットル開度演算部10Kが、目標スロットル開度信号をエンジンコントローラ12へ出力する。
このため、加速抑制制御作動条件が成立した状態では、自車両Vの車速が低いほど、加速指令値を高い抑制度合いで抑制する。
なお、上述した車輪速センサ16及び自車両車速演算部10Bは、車速検出部に対応する。
また、上述したように、本実施形態の車両用加速抑制方法は、自車両Vの車速が高いほど、アクセルペダル32の操作量に応じた加速指令値を低い抑制度合いで抑制する方法である。
以下、本実施形態の効果を記載する。
本実施形態では、上述した第一実施形態の効果に加え、さらに、以下に記載する効果を奏することが可能となる。
(1)車輪速センサ16及び自車両車速演算部10Bにより、自車両Vの車速を検出する。これに加え、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kが、自車両Vの車速が高いほど、加速指令値を低い抑制度合いで抑制する。すなわち、加速抑制制御開始タイミング演算部42、加速抑制制御量演算部44、加速抑制指令値演算部10J、目標スロットル開度演算部10Kは、自車両Vの車速が低いほど、加速指令値を高い抑制度合いで抑制する。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
このため、自車両Vの車速が高く、運転者が自車両Vの駐車を意図していない可能性が高い場合には、自車両Vの車速が低く、運転者が自車両Vの駐車を意図している可能性が高い場合よりも、加速指令値の抑制度合いを低くする。これにより、運転性の低下を少なくすることが可能となる。さらに、自車両Vの車速が低く、運転者が自車両Vの駐車を意図している可能性が高い場合には、自車両Vの車速が高く、運転者が自車両Vの駐車を意図していない可能性が高い場合よりも、加速指令値の抑制度合いを高くする。これにより、自車両Vの加速抑制効果を高くすることが可能となる。
その結果、駐車時における自車両Vの運転性低下を抑制するとともに、アクセルペダル32の誤操作時における自車両Vの加速を抑制することが可能となる。
(1)本実施形態では、自車両Vの車速が高いほど、総合確信度を低いレベルとして算出されやすくして、加速指令値の抑制度合いが低くなる構成としているが、これに限定するものではない。すなわち、例えば、加速抑制制御開始タイミングや加速抑制制御量を変化させて、自車両Vの車速が高いほど、加速指令値の抑制度合いを低くする構成としてもよい。また、例えば、自車両Vの車速が高いほど、駐車枠確信度や駐車枠進入確信度を低いレベルとして算出されやすくして、加速指令値の抑制度合いが低くなる構成としてもよい。
以上、本願が優先権を主張する日本国特許出願2012-259210(2012年11月27日出願)の全内容は、参照により本開示の一部をなす。
ここでは、限られた数の実施形態を参照しながら説明したが、権利範囲はそれらに限定されるものではなく、上記の開示に基づく各実施形態の改変は当業者にとって自明なことである。
2 ブレーキ装置
4 流体圧回路
6 ブレーキコントローラ
8 エンジン
10 走行制御コントローラ
10A 周囲環境認識情報演算部
10B 自車両車速演算部
10C 操舵角演算部
10D 操舵角速度演算部
10E シフトポジション演算部
10F ブレーキペダル操作情報演算部
10G アクセル操作量演算部
10H アクセル操作速度演算部
10I 加速抑制制御内容演算部
10J 加速抑制指令値演算部
10K 目標スロットル開度演算部
12 エンジンコントローラ
14 周囲環境認識センサ(前方カメラ14F、右側方カメラ14SR、左側方カメラ14SL、後方カメラ14R)
16 車輪速センサ
18 操舵角センサ
20 シフトポジションセンサ
22 ブレーキ操作検出センサ
24 アクセル操作検出センサ
26 ナビゲーション装置
28 ステアリングホイール
30 ブレーキペダル
32 アクセルペダル
34 加速抑制作動条件判断部
36 駐車枠確信度算出部
38 駐車枠進入確信度算出部
40 総合確信度算出部
42 加速抑制制御開始タイミング演算部
44 加速抑制制御量演算部
V 自車両
W 車輪(右前輪WFR、左前輪WFL、右後輪WRR、左後輪WRL)
Claims (7)
- 運転者が操作して駆動力を指示する駆動力指示操作子の操作量に応じた自車両の加速を抑制することで、前記駆動力を抑制制御する車両用加速抑制装置であって、
前記駆動力指示操作子の操作量である駆動力操作量を検出する駆動力操作量検出部と、
前記駆動力操作量検出部が検出した駆動力操作量に応じて、前記自車両の加速を制御する加速制御部と、
前記自車両に設けた周囲環境認識センサの検出情報に基づいて自車両周囲の環境を認識する周囲環境認識部と、
前記自車両の車速を検出する車速検出部と、
前記周囲環境認識部が認識した環境に基づいて、前記自車両の進行方向に駐車枠が存在する確信の度合いを示す駐車枠確信度を算出する駐車枠確信度算出部と、
前記駐車枠確信度算出部が算出した駐車枠確信度と、前記車速検出部が検出した車速と、に基づいて、前記加速制御部が制御する加速を抑制する加速抑制部と、を備え、
前記加速抑制部は、前記車速検出部が検出した車速が高いほど、前記加速の抑制度合いを低くすることを特徴とする車両用加速抑制装置。 - 前記自車両の走行状態を検出する自車両走行状態検出部と、
前記周囲環境認識部が認識した環境と、前記自車両走行状態検出部が検出した走行状態と、に基づいて、前記自車両が前記駐車枠へ進入する確信の度合いを示す駐車枠進入確信度を算出する駐車枠進入確信度算出部と、
前記駐車枠確信度算出部が算出した駐車枠確信度及び前記駐車枠進入確信度算出部が算出した駐車枠進入確信度に基づいて、前記駐車枠確信度と前記駐車枠進入確信度との総合的な確信の度合いを示す総合確信度を算出する総合確信度算出部と、を備え、
前記加速抑制部は、前記総合確信度算出部が算出した総合確信度が低いときは、算出した総合確信度が高いときに比べて、前記加速の抑制度合いを低くすることを特徴とする請求項1に記載した車両用加速抑制装置。 - 前記自車両の現在位置を検出する自車両現在位置検出部と、
前記自車両が走行する道路の道路種別を検出する自車両走行路種別検出部と、を備え、
前記駐車枠確信度算出部は、前記自車両現在位置検出部が検出した現在位置と、前記自車両走行路種別検出部が検出した道路種別と、を用いて、前記駐車枠確信度を算出することを特徴とする請求項1または請求項2に記載した車両用加速抑制装置。 - 前記加速抑制部は、前記加速制御部が制御する加速の抑制を開始するタイミングである加速抑制制御開始タイミングを遅れさせて、前記加速の抑制度合いを低くすることを特徴とする請求項1から請求項3のうちいずれか1項に記載した車両用加速抑制装置。
- 前記加速抑制部は、前記加速制御部が制御する加速を抑制するための制御量である加速抑制制御量を減少させて、前記加速の抑制度合いを低くすることを特徴とする請求項1から請求項4のうちいずれか1項に記載した車両用加速抑制装置。
- 運転者が操作して駆動力を指示する駆動力指示操作子の操作量に応じた自車両の加速を抑制することで、前記駆動力を抑制制御する車両用加速抑制方法であって、
前記駆動力指示操作子の操作量である駆動力操作量と、前記自車両の車速と、を検出し、
前記自車両周囲の環境を認識し、
前記認識した環境に基づいて前記自車両の進行方向に駐車枠が存在する確信の度合いを示す駐車枠確信度を算出し、
前記検出した車速が高いほど、前記検出した駆動力操作量に応じて制御する前記自車両の加速を低い抑制度合いで抑制することを特徴とする車両用加速抑制方法。 - 前記自車両の走行状態を検出し、
前記認識した環境及び検出した走行状態に基づいて、前記自車両が前記駐車枠へ進入する確信の度合いを示す駐車枠進入確信度を算出し、
前記算出した駐車枠確信度及び駐車枠進入確信度に基づいて、前記駐車枠確信度と前記駐車枠進入確信度との総合的な確信の度合いを示す総合確信度を算出し、
前記算出した総合確信度が低いときは、算出した総合確信度が高いときに比べて、前記加速を低い抑制度合いで抑制することを特徴とする請求項6に記載した車両用加速抑制方法。
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2014549816A JP5915769B2 (ja) | 2012-11-27 | 2013-11-22 | 車両用加速抑制装置及び車両用加速抑制方法 |
US14/646,312 US9457806B2 (en) | 2012-11-27 | 2013-11-22 | Vehicular acceleration suppression device and vehicular acceleration suppression method |
CN201380058775.8A CN104781123B (zh) | 2012-11-27 | 2013-11-22 | 车辆用加速抑制装置以及车辆用加速抑制方法 |
EP13859064.1A EP2927080B1 (en) | 2012-11-27 | 2013-11-22 | Vehicle acceleration-suppression device, and vehicle acceleration-suppression method |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2012259210 | 2012-11-27 | ||
JP2012-259210 | 2012-11-27 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2014083823A1 true WO2014083823A1 (ja) | 2014-06-05 |
Family
ID=50827484
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/JP2013/006881 WO2014083823A1 (ja) | 2012-11-27 | 2013-11-22 | 車両用加速抑制装置及び車両用加速抑制方法 |
Country Status (5)
Country | Link |
---|---|
US (1) | US9457806B2 (ja) |
EP (1) | EP2927080B1 (ja) |
JP (1) | JP5915769B2 (ja) |
CN (1) | CN104781123B (ja) |
WO (1) | WO2014083823A1 (ja) |
Families Citing this family (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9493070B2 (en) * | 2012-11-27 | 2016-11-15 | Nissan Motor Co., Ltd. | Vehicle acceleration suppression device and vehicle acceleration suppression method |
CN104781121B (zh) * | 2012-11-27 | 2016-08-17 | 日产自动车株式会社 | 车辆用加速抑制装置以及车辆用加速抑制方法 |
JP2017030569A (ja) * | 2015-07-31 | 2017-02-09 | アイシン精機株式会社 | 駐車支援装置 |
KR20170030811A (ko) * | 2015-09-10 | 2017-03-20 | 주식회사 만도 | 운전지원장치 및 운전지원방법 |
KR101964919B1 (ko) * | 2017-05-26 | 2019-08-13 | 주식회사 만도 | 주차 제어 장치 및 그 방법 |
KR102001917B1 (ko) * | 2017-05-29 | 2019-07-19 | 엘지전자 주식회사 | 차량용 주차 시스템 및 차량 |
US11127297B2 (en) * | 2017-07-17 | 2021-09-21 | Veoneer Us, Inc. | Traffic environment adaptive thresholds |
GB2570908B (en) * | 2018-02-09 | 2020-07-15 | Ford Global Tech Llc | A method of operating a vehicle |
JP2019206206A (ja) * | 2018-05-28 | 2019-12-05 | トヨタ自動車株式会社 | 駆動力制御装置 |
JP6984558B2 (ja) * | 2018-07-26 | 2021-12-22 | トヨタ自動車株式会社 | 車両走行支援装置 |
JP7229804B2 (ja) * | 2019-02-14 | 2023-02-28 | フォルシアクラリオン・エレクトロニクス株式会社 | 画像処理装置及び画像処理方法 |
JP7322826B2 (ja) * | 2020-07-03 | 2023-08-08 | トヨタ自動車株式会社 | 車両進行方向推定装置 |
US20230294699A1 (en) * | 2022-03-16 | 2023-09-21 | Toyota Research Institute, Inc. | Acceleration control to prevent collisions |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2003137001A (ja) | 2001-11-06 | 2003-05-14 | Denso Corp | 乗物の安全装置及び乗物の安全運転方法をコンピュータに実現させるためのコンピュータプログラム |
JP2007055535A (ja) * | 2005-08-26 | 2007-03-08 | Toyota Motor Corp | 自動車およびその制御方法 |
JP2012087692A (ja) * | 2010-10-20 | 2012-05-10 | Fujitsu Ltd | 車載装置、車両および制御方法 |
WO2013061378A1 (ja) * | 2011-10-28 | 2013-05-02 | トヨタ自動車株式会社 | 車両の制御装置 |
Family Cites Families (44)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP3518464B2 (ja) * | 2000-02-18 | 2004-04-12 | 日産自動車株式会社 | 四輪駆動車の駆動力配分制御装置 |
JP3749483B2 (ja) * | 2002-01-11 | 2006-03-01 | トヨタ自動車株式会社 | 駐車支援装置 |
JP2004322787A (ja) * | 2003-04-23 | 2004-11-18 | Nissan Motor Co Ltd | 車線逸脱防止装置 |
DE102004043487B4 (de) * | 2003-09-09 | 2010-06-10 | Mitsubishi Jidosha Kogyo K.K. | Antriebskraftverteilungs- und Steuervorrichtung für ein Fahrzeug |
DE10343174A1 (de) * | 2003-09-18 | 2005-04-14 | Robert Bosch Gmbh | Vorrichtung und Verfahren zur Regelung der Geschwindigkeit eines Fahrzeugs beim Rangieren/Einparken des Fahrzeugs |
JP2005147055A (ja) * | 2003-11-18 | 2005-06-09 | Nissan Motor Co Ltd | 車両の駆動力制御装置 |
JP4389567B2 (ja) * | 2003-12-03 | 2009-12-24 | 日産自動車株式会社 | 車線逸脱防止装置 |
JP2005178626A (ja) * | 2003-12-19 | 2005-07-07 | Toyota Motor Corp | 車両の統合制御システム |
JP2005196326A (ja) * | 2004-01-05 | 2005-07-21 | Honda Motor Co Ltd | 走行制限信号送信装置および走行制限装置 |
JP3977368B2 (ja) * | 2004-09-30 | 2007-09-19 | クラリオン株式会社 | 駐車支援システム |
US8954251B2 (en) * | 2004-10-05 | 2015-02-10 | Vision Works Ip Corporation | Absolute acceleration sensor for use within moving vehicles |
US8903617B2 (en) * | 2004-10-05 | 2014-12-02 | Vision Works Ip Corporation | Absolute acceleration sensor for use within moving vehicles |
US9878693B2 (en) * | 2004-10-05 | 2018-01-30 | Vision Works Ip Corporation | Absolute acceleration sensor for use within moving vehicles |
JP4131270B2 (ja) * | 2005-03-01 | 2008-08-13 | トヨタ自動車株式会社 | 車輌の制駆動力制御装置 |
JP4414959B2 (ja) * | 2005-11-16 | 2010-02-17 | アイシン精機株式会社 | 駐車支援装置 |
JP2010502515A (ja) * | 2006-09-12 | 2010-01-28 | コンティネンタル・テーベス・アクチエンゲゼルシヤフト・ウント・コンパニー・オッフェネ・ハンデルスゲゼルシヤフト | 自動車の走行方向を検出するための方法 |
JP2008095635A (ja) * | 2006-10-13 | 2008-04-24 | Toyota Motor Corp | 駆動力制御装置 |
JP2008145152A (ja) * | 2006-12-07 | 2008-06-26 | Nissan Motor Co Ltd | 加速度検出装置および加速度センサのドリフト誤差補正方法 |
JP4556945B2 (ja) * | 2006-12-07 | 2010-10-06 | 日産自動車株式会社 | 加速度検出装置および加速度センサのドリフト誤差補正方法ならびにそれを用いたニュートラル制御装置 |
JP2008143430A (ja) * | 2006-12-12 | 2008-06-26 | Toyota Motor Corp | 駐車支援装置 |
US20100066515A1 (en) * | 2006-12-28 | 2010-03-18 | Kabushiki Kaisha Toyota Jidoshokki | Parking assistance apparatus, parking assistance apparatus part, parking assist method, parking assist program, vehicle travel parameter calculation method, vehicle travel parameter calculation program, vehicle travel parameter calculation apparatus and vehicle travel parameter calculation apparatus part |
US8170752B2 (en) * | 2007-07-31 | 2012-05-01 | Kabushiki Kaisha Toyota Jidoshokki | Parking assistance apparatus, vehicle-side apparatus of parking assistance apparatus, parking assist method, and parking assist program |
KR20090088210A (ko) * | 2008-02-14 | 2009-08-19 | 주식회사 만도 | 두 개의 기준점을 이용한 목표주차위치 검출 방법과 장치및 그를 이용한 주차 보조 시스템 |
JP5257689B2 (ja) * | 2009-03-11 | 2013-08-07 | アイシン精機株式会社 | 駐車支援装置 |
CN101554836B (zh) * | 2009-05-19 | 2011-06-29 | 浙江大学 | 限速感应及车速控制装置 |
JP5327630B2 (ja) * | 2009-09-17 | 2013-10-30 | スズキ株式会社 | 後方画像表示切替装置及び方法 |
WO2011105105A1 (ja) * | 2010-02-26 | 2011-09-01 | パナソニック株式会社 | 駐車支援装置 |
JP5605617B2 (ja) * | 2010-05-26 | 2014-10-15 | アイシン精機株式会社 | 駐車支援装置 |
US20110295477A1 (en) * | 2010-05-28 | 2011-12-01 | Chun-Chih Wang | Device for preventing sudden acceleration of vehicle |
US8948990B2 (en) * | 2010-06-25 | 2015-02-03 | Nissan Motor Co., Ltd. | Parking assist control apparatus and control method |
JP5476268B2 (ja) * | 2010-09-29 | 2014-04-23 | 富士重工業株式会社 | 速度制限装置 |
JP5218532B2 (ja) * | 2010-12-01 | 2013-06-26 | 株式会社日本自動車部品総合研究所 | 運転支援装置および運転支援システム |
US9481375B2 (en) * | 2010-12-03 | 2016-11-01 | Pedal Logic Lp | Method and apparatus to adjust for undesired force influencing a vehicle input control |
EP2687705B1 (en) * | 2011-03-18 | 2019-12-25 | Honda Motor Co., Ltd. | Engine control apparatus, and engine control method |
JP6000693B2 (ja) * | 2012-07-03 | 2016-10-05 | 日立オートモティブシステムズ株式会社 | 駐車支援装置 |
CN104755344B (zh) * | 2012-11-27 | 2016-05-04 | 日产自动车株式会社 | 车辆用加速抑制装置以及车辆用加速抑制方法 |
JP5862799B2 (ja) * | 2012-11-27 | 2016-02-16 | 日産自動車株式会社 | 車両用加速抑制装置及び車両用加速抑制方法 |
EP2927079B1 (en) * | 2012-11-27 | 2018-01-31 | Nissan Motor Co., Ltd | Acceleration restriction device for vehicle and acceleration restriction method for vehicle |
EP2927075B1 (en) * | 2012-11-27 | 2017-04-05 | Nissan Motor Co., Ltd. | Vehicle acceleration suppression device and vehicle acceleration suppression method |
WO2014083764A1 (ja) * | 2012-11-27 | 2014-06-05 | 日産自動車株式会社 | 加減速誤操作判定装置、誤操作加速抑制制御装置、加減速誤操作判定方法 |
US9493070B2 (en) * | 2012-11-27 | 2016-11-15 | Nissan Motor Co., Ltd. | Vehicle acceleration suppression device and vehicle acceleration suppression method |
US9393869B2 (en) * | 2012-11-27 | 2016-07-19 | Nissan Motor Co., Ltd. | Vehicle acceleration suppression device and vehicle acceleration suppression method |
KR101878690B1 (ko) * | 2013-08-05 | 2018-08-20 | 주식회사 만도 | 주차 동작 제어 장치 및 그 제어 방법 |
JP5949840B2 (ja) * | 2014-06-19 | 2016-07-13 | トヨタ自動車株式会社 | 駐車支援装置 |
-
2013
- 2013-11-22 JP JP2014549816A patent/JP5915769B2/ja active Active
- 2013-11-22 EP EP13859064.1A patent/EP2927080B1/en active Active
- 2013-11-22 US US14/646,312 patent/US9457806B2/en active Active
- 2013-11-22 WO PCT/JP2013/006881 patent/WO2014083823A1/ja active Application Filing
- 2013-11-22 CN CN201380058775.8A patent/CN104781123B/zh active Active
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2003137001A (ja) | 2001-11-06 | 2003-05-14 | Denso Corp | 乗物の安全装置及び乗物の安全運転方法をコンピュータに実現させるためのコンピュータプログラム |
JP2007055535A (ja) * | 2005-08-26 | 2007-03-08 | Toyota Motor Corp | 自動車およびその制御方法 |
JP2012087692A (ja) * | 2010-10-20 | 2012-05-10 | Fujitsu Ltd | 車載装置、車両および制御方法 |
WO2013061378A1 (ja) * | 2011-10-28 | 2013-05-02 | トヨタ自動車株式会社 | 車両の制御装置 |
Non-Patent Citations (1)
Title |
---|
See also references of EP2927080A4 |
Also Published As
Publication number | Publication date |
---|---|
US20150284000A1 (en) | 2015-10-08 |
JP5915769B2 (ja) | 2016-05-11 |
JPWO2014083823A1 (ja) | 2017-01-05 |
CN104781123A (zh) | 2015-07-15 |
EP2927080B1 (en) | 2017-05-31 |
EP2927080A4 (en) | 2016-05-18 |
EP2927080A1 (en) | 2015-10-07 |
US9457806B2 (en) | 2016-10-04 |
CN104781123B (zh) | 2016-08-24 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
JP5915771B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5915769B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5999195B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5915770B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5994865B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
WO2014083827A1 (ja) | 車両用加速抑制装置 | |
JP5991382B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP6007991B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP6155944B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5892259B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5900648B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP2015030363A (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5846318B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5892260B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5900647B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 | |
JP5900650B2 (ja) | 車両用加速抑制装置及び車両用加速抑制方法 |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 13859064 Country of ref document: EP Kind code of ref document: A1 |
|
ENP | Entry into the national phase |
Ref document number: 2014549816 Country of ref document: JP Kind code of ref document: A |
|
WWE | Wipo information: entry into national phase |
Ref document number: 14646312 Country of ref document: US |
|
NENP | Non-entry into the national phase |
Ref country code: DE |
|
REEP | Request for entry into the european phase |
Ref document number: 2013859064 Country of ref document: EP |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2013859064 Country of ref document: EP |