WO2012073358A1 - 車両の運動制御装置 - Google Patents
車両の運動制御装置 Download PDFInfo
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- WO2012073358A1 WO2012073358A1 PCT/JP2010/071511 JP2010071511W WO2012073358A1 WO 2012073358 A1 WO2012073358 A1 WO 2012073358A1 JP 2010071511 W JP2010071511 W JP 2010071511W WO 2012073358 A1 WO2012073358 A1 WO 2012073358A1
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- vehicle
- control
- target
- yaw rate
- slip angle
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Classifications
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- B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
- B62D—MOTOR VEHICLES; TRAILERS
- B62D6/00—Arrangements for automatically controlling steering depending on driving conditions sensed and responded to, e.g. control circuits
- B62D6/002—Arrangements for automatically controlling steering depending on driving conditions sensed and responded to, e.g. control circuits computing target steering angles for front or rear wheels
- B62D6/003—Arrangements for automatically controlling steering depending on driving conditions sensed and responded to, e.g. control circuits computing target steering angles for front or rear wheels in order to control vehicle yaw movement, i.e. around a vertical axis
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- 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
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- B60W10/00—Conjoint control of vehicle sub-units of different type or different function
- B60W10/18—Conjoint control of vehicle sub-units of different type or different function including control of braking systems
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- 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
- B60W10/00—Conjoint control of vehicle sub-units of different type or different function
- B60W10/18—Conjoint control of vehicle sub-units of different type or different function including control of braking systems
- B60W10/184—Conjoint control of vehicle sub-units of different type or different function including control of braking systems with wheel brakes
- B60W10/188—Conjoint control of vehicle sub-units of different type or different function including control of braking systems with wheel brakes hydraulic brakes
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- B60W10/00—Conjoint control of vehicle sub-units of different type or different function
- B60W10/20—Conjoint control of vehicle sub-units of different type or different function including control of steering systems
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- 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
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- B60W30/045—Improving turning performance
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- 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
- B60W50/02—Ensuring safety in case of control system failures, e.g. by diagnosing, circumventing or fixing failures
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- 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
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- 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
- B60W50/02—Ensuring safety in case of control system failures, e.g. by diagnosing, circumventing or fixing failures
- B60W50/035—Bringing the control units into a predefined state, e.g. giving priority to particular actuators
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
- B62D—MOTOR VEHICLES; TRAILERS
- B62D15/00—Steering not otherwise provided for
- B62D15/02—Steering position indicators ; Steering position determination; Steering aids
- B62D15/025—Active steering aids, e.g. helping the driver by actively influencing the steering system after environment evaluation
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
- B62D—MOTOR VEHICLES; TRAILERS
- B62D7/00—Steering linkage; Stub axles or their mountings
- B62D7/06—Steering linkage; Stub axles or their mountings for individually-pivoted wheels, e.g. on king-pins
- B62D7/14—Steering linkage; Stub axles or their mountings for individually-pivoted wheels, e.g. on king-pins the pivotal axes being situated in more than one plane transverse to the longitudinal centre line of the vehicle, e.g. all-wheel steering
- B62D7/15—Steering linkage; Stub axles or their mountings for individually-pivoted wheels, e.g. on king-pins the pivotal axes being situated in more than one plane transverse to the longitudinal centre line of the vehicle, e.g. all-wheel steering characterised by means varying the ratio between the steering angles of the steered wheels
- B62D7/159—Steering linkage; Stub axles or their mountings for individually-pivoted wheels, e.g. on king-pins the pivotal axes being situated in more than one plane transverse to the longitudinal centre line of the vehicle, e.g. all-wheel steering characterised by means varying the ratio between the steering angles of the steered wheels characterised by computing methods or stabilisation processes or systems, e.g. responding to yaw rate, lateral wind, load, road condition
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- 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
- B60W2050/0062—Adapting control system settings
- B60W2050/0075—Automatic parameter input, automatic initialising or calibrating means
- B60W2050/009—Priority selection
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- B60W2720/00—Output or target parameters relating to overall vehicle dynamics
- B60W2720/14—Yaw
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- 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
- B60W2720/20—Sideslip angle
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- 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
- B60W2720/40—Torque distribution
- B60W2720/406—Torque distribution between left and right wheel
Definitions
- the present invention relates to a technical field of a vehicle motion control device applicable to a vehicle having various automatic driving functions such as LKA (Lane (Keeping Assist).
- Patent Document 1 There is a vehicle motion control device disclosed in Patent Document 1 as this type of device. According to this apparatus, when slip angle control and yaw moment control are performed by separate apparatuses, when one apparatus fails, the other apparatus performs control to compensate for control on the failed side.
- each of the VSA and the RTC is based on the yaw rate acquired from the cooperation control unit.
- There has also been proposed one that performs control based on the yaw rate calculated within the device itself in the event of an abnormality see Patent Document 2.
- JP 2008-126916 A JP 2010-023787 A JP 2009-274670 A JP 2006-036203 A JP-A-6-336169 JP 2010-023788
- the state control amount can be controlled independently. 2 or more are required.
- Patent Document 1 discloses a device configuration that can independently control slip angle control and yaw moment control, a failure of one device is
- the device disclosed in Patent Document 1 is not subject to any case where the number of state control amounts that can be independently controlled decreases due to, for example, a temporary or permanent malfunction of the device, or for some other reason. It does not give a solution. This also applies to the devices disclosed in Patent Documents 2 and 3.
- the situation in which the quantity of state control amounts that can be controlled independently decreases does not necessarily occur only when the device has failed, such as a temporary increase in control load or thermal load. Depending on the situation, this kind of situation may occur temporarily. In view of these points, it is desirable that a clear control guide for such a case is given in advance from the viewpoint of maintaining the vehicle behavior optimally at all times.
- the conventional technique including the device disclosed in Patent Document 1 includes a state in which a plurality of vehicle state quantities are controlled independently from each other by controlling a plurality of state control quantities having controllability.
- the present invention has been made in view of such technical problems, and even when it is necessary to perform behavior control of a vehicle using a plurality of devices that promote change in the state control amount by one device, It is an object of the present invention to provide a vehicle motion control device capable of maintaining an optimal vehicle behavior as much as possible.
- a vehicle motion control device that controls the motion of a vehicle including a plurality of devices each capable of selectively controlling a slip angle or a yaw rate, the target slip being a target value of the slip angle
- Target slip angle setting means for setting an angle
- target yaw rate setting means for setting a target yaw rate as a target value of the yaw rate, and so that the slip angle and yaw rate become the set target slip angle and target yaw rate, respectively.
- the behavior control means for executing the behavior control for controlling the plurality of devices, the turning state quantity specifying means for specifying the turning state quantity of the vehicle, and the behavior control is executed by one of the plurality of devices.
- the vehicle according to the present invention includes a plurality of devices each capable of selectively controlling a slip angle (hereinafter, “slip angle” according to the present invention means a vehicle body slip angle) or a yaw rate. That is, the plurality of devices have one state control amount that promotes a change in one of the vehicle state amounts whose change includes at least a slip angle and a yaw rate, for example, physical, electrical, or mechanical constraints. Includes devices that can be freely controlled within the scope.
- the state control amount capable of prompting the change in the slip angle and the yaw rate means, for example, a front wheel steering angle, a rear wheel steering angle, a front wheel braking / driving force difference, a rear wheel braking / driving force difference, or the like. To do.
- the vehicle motion control device of the present invention is a device for controlling a vehicle including such a plurality of devices, for example, one or a plurality of CPUs (Central Processing Unit), MPU (Micro Processing Unit), various processors or Various processing units such as single or plural ECUs, various controllers, which may appropriately include various storage means such as various controllers, or ROM (Read Only Memory), RAM (Random Access Memory), buffer memory or flash memory Alternatively, various computer systems such as a microcomputer device may be employed.
- CPUs Central Processing Unit
- MPU Micro Processing Unit
- various processing units such as single or plural ECUs
- various controllers which may appropriately include various storage means such as various controllers, or ROM (Read Only Memory), RAM (Random Access Memory), buffer memory or flash memory
- ROM Read Only Memory
- RAM Random Access Memory
- buffer memory or flash memory
- various computer systems such as a microcomputer device may be employed.
- the target slip angle is set by the target slip angle setting means
- the target yaw rate is set by the target yaw rate setting means.
- the target value set by each setting means may be, for example, a target value for causing the vehicle to follow the target travel path (for example, LKA or the like corresponds to this type of control).
- the target value may be set for any purpose.
- behavior control is executed by the behavior control means.
- the behavior control means control for realizing two-degree-of-freedom vehicle motion control performed on the plurality of devices such that the slip angle and the yaw rate become the set target values.
- each of the plurality of devices is configured to be able to control one state control amount, and the number of state control amounts that can be controlled by independent control of the plurality of devices is the plurality of these state control amounts.
- the number of state control amounts matches the degree of freedom of the vehicle state amount, so two types of vehicles, slip angle and yaw rate, are controlled by controlling the state control amount via these multiple devices. This allows two-degree-of-freedom vehicle motion in which the state quantities are independently controlled.
- behavior control is more strictly control for realizing vehicle motion with at least two degrees of freedom.
- the target value of the state control amount for realizing the target slip angle and the target yaw rate can be obtained, for example, by numerically solving a vehicle motion model constructed based on this vehicle motion equation.
- the target value obtained in this way is mapped in advance, it can be obtained by appropriately selecting the corresponding value from the map.
- the vehicle motion control apparatus is tentative and alternative when it is difficult to maintain the vehicle motion control with the minimum two degrees of freedom including the slip angle and the yaw rate that are originally desired. Or provide clear guidance on implementing suboptimal measures.
- the turning state quantity specifying means specifies the turning state quantity of the vehicle, and the selection means determines the slip angle and yaw rate based on the specified turning state quantity. Select the one that should be prioritized.
- the behavior control means described above controls one apparatus so that the selected one becomes the set target value.
- “specific” according to the present invention means to finally determine to use as a reference value for control, and its practical aspect is detection, calculation, derivation, estimation, and identification. This is a wide variety of good intentions such as selection or acquisition.
- the turning state quantity is a state quantity that serves as an index for defining the turning behavior at that point in the behavior control process of the present invention including the two-degree-of-freedom vehicle motion control in which the slip angle and the yaw rate are controlled.
- the yaw rate among the vehicle state quantities is a vehicle state quantity suitable for controlling the turning behavior as compared with the slip angle. Therefore, by using the turning behavior as a criterion, it is possible to accurately select a vehicle state quantity that requires controllability more preferentially at that time out of the slip angle and the yaw rate. For example, in a qualitative expression, it can be determined that priority should be given to maintaining a turning state when the vehicle is turning, and maintaining a straight state when the vehicle is traveling straight. It goes without saying that the behavior control means newly sets a control target for the vehicle state quantity as appropriate based on the selected one of the vehicle state quantities to be prioritized and the target value, and uses it for actual control.
- “to be prioritized” means that one vehicle state quantity is selected and the other vehicle state quantity is not selected.
- the degree of freedom of movement is one degree of freedom, it may include stepwise or continuous priority modes such as weighting the control time ratio within a predetermined period.
- the selection means selects and selects one of the vehicle state quantities to be prioritized from the slip angle and the yaw rate, with the turning state quantity as a selection criterion.
- the other control is given priority. For this reason, even if it becomes necessary to perform behavior control with one of a plurality of devices, for example, it is given to vehicle motion as a provisional, alternative or suboptimal measure until this behavior control is terminated. Effectively using the one degree of freedom, and continuing the control of the vehicle motion with one degree of freedom for the vehicle state quantity to be prioritized at that time, and terminating the behavior control so as not to adversely affect the vehicle behavior Can do.
- each of the plurality of devices includes a first device and a second device each capable of selectively controlling a slip angle or a yaw rate, and the vehicle motion control device. Further comprises a function restriction state determination means for determining whether at least one of the first and second devices is in a function restriction state, and the selection means performs behavior control with the one device.
- the behavior control means selects the selected one as the selection
- One of the first and second devices that is not in the function-restricted state is controlled as the one device so that the target value corresponding to one of the two is set (Claim 2).
- the plurality of devices may include the first and second devices as devices that realize independent control of the slip angle and the yaw rate related to the behavior control through the control of the state control amount as a preferred embodiment.
- “when it is necessary to execute behavior control with one device” according to the present invention is defined as a case where one of the first and second devices is in a function-restricted state.
- the “function restricted state” is a concept that broadly encompasses a state in which functions that should be originally expected are restricted regardless of whether they are permanent or temporary.
- a function-restricted state for example, when a part or the whole of the device fails, when an abnormality occurs in a part or the whole of the device, or the load state (processing load, electrical load, Or a thermal load or the like) temporarily or permanently overloaded.
- Whether or not one of the first and second devices is in a function-restricted state is determined so as to be able to determine whether or not at least one of the first and second devices is in a function-restricted state.
- the function limiting means for example, changes in the actual state control amount with respect to the control amount change that prompts the change in the state control amount, changes in the selectable area of the control amount that prompts the change in the state control amount, or the degree of processing load
- the determination can be executed without delay based on a change in the operating environment.
- the first device is a front wheel steering angle variable device capable of changing the front wheel steering angle independently of a driver operation that promotes a change in the front wheel steering angle.
- the second device is a rear wheel steering angle variable device capable of changing the rear wheel steering angle independently of a driver operation that promotes the change of the rear wheel steering angle.
- the front wheel and rear wheel rudder angle varying device is a device that can change the rudder angle of the front wheels and rear wheels independently of the driver operation that promotes these changes.
- This driver operation preferably means an operation of various steering input means such as a steering wheel. Therefore, according to the front wheel and rear wheel steering angle variable device, the steering angle is changed to a desired value even if the driver releases his hand from the steering wheel or only keeps the steering. It is possible.
- the front wheel and rear wheel rudder angle varying device differs in essential meaning from a normal steering mechanism that takes a mechanical transmission path of steering input from various steering input means to the steering wheel (preferably, the front wheel). It is. However, from the viewpoint of the physical configuration, at least a part of the front wheel and rear wheel steering angle varying device may be shared or shared with this type of steering mechanism.
- the front wheel rudder angle varying device may be a VGRS (Variable Gear Ratio Steering), and the rear wheel rudder angle varying device may be an ARS (ActiveearRear) as a preferred embodiment. Steering: rear wheel steering device).
- front wheel and rear wheel rudder angle varying devices can change the front wheel rudder angle and rear wheel rudder angle, which are state control amounts, at least within a certain range with respect to the wheels to be controlled by the rudder angle. Therefore, it is possible to change the traveling direction of the vehicle regardless of the steering input of the driver, which is suitable as a device that promotes the change of the vehicle state quantity including the slip angle and the yaw rate.
- the plurality of devices further include a third device different from the first and second devices capable of selectively controlling the slip angle or the yaw rate, and the behavior
- the control means controls the third device so that the selected one becomes a target value corresponding to the selected one when both the first and second devices are in the function restriction state.
- the vehicle when the vehicle includes the third device different from the first and second devices, and it is determined by the function restriction state determination means that both the first and second devices are in the function restriction state.
- the third device is controlled by the behavior control means. Therefore, even if both the first and second devices are in a function-limited state, vehicle motion control with one degree of freedom is possible, which is useful in practice.
- the third device may be a braking / driving force variable device capable of changing the left / right braking / driving force difference between the front wheels and the rear wheels.
- the variable braking / driving force device is a device capable of changing the left / right braking / driving force difference (the difference in braking / driving force between the left and right wheels) at the front wheel, the rear wheel, or both.
- the variable braking / driving force device includes, for example, various driving force variable devices including a driving force distribution differential mechanism or an in-wheel motor system, or various ECB (Electronic Controlled) including ABS (Antilock Braking System).
- Various types of braking force variable devices including Braking system (electronically controlled braking device) and the like, or both of them can be used. Note that “the right / left braking / driving force difference can be changed” means that “the braking / driving forces of the left and right wheels can be changed independently from each other”.
- the braking / driving force variable device is a driving force variable device
- torque supplied from various power sources such as an internal combustion engine (the torque and the driving force may have a unique relationship) is fixed or After being distributed to the front and rear wheels at a variable distribution ratio, the torque distributed to each of the front and rear wheels is further distributed to the left and right wheels at a desired distribution ratio.
- the absolute value of the driving force of the left and right wheels is controlled to increase / decrease, and a left / right driving force difference can occur.
- a driving force that is independent of the engine torque is applied to the left and right wheels, and as a result of the increase / decrease control of the absolute value of the driving force of the left and right wheels, a difference between the left and right driving forces can occur.
- the braking / driving force varying device is a braking force varying device
- the braking force applied to the left and right wheels, and preferably the braking force as the friction braking force is made variable, so that For the wheel, it is possible to obtain the same effect as relatively increasing the driving force. That is, the braking force is a negative driving force.
- the vehicle when a braking / driving force difference is generated between the left and right wheels, the vehicle is driven on the side of the wheel having a relatively small driving force (that is, a wheel having a relatively large braking force) (that is, the driving force of the right wheel ( If the braking force is small (if it is large), turn to the right). Therefore, according to the braking / driving force variable device, it is theoretically possible to change the traveling direction of the vehicle irrespective of the steering input of the driver. That is, the braking / driving force varying device is also suitable as a device that promotes changes in the slip angle and the yaw rate.
- the function restriction state includes at least one of a failure state and a state in which a selection range of a control amount is restricted (Claim 6).
- the specifying means specifies the turning degree of the vehicle as the turning state quantity (Claim 7).
- the turning degree is a numerical index that can represent the turning state stepwise or continuously, and is suitable as a turning state amount.
- the turning degree may be, for example, the yaw rate (the larger the turning degree, the larger the turning degree), the radius of the travel path (the smaller the turning degree, the larger the turning degree), or the lateral acceleration (the larger the turning degree, the larger the turning degree).
- the selection means selects the yaw rate as the one to be prioritized when the specified turning degree is equal to or higher than a reference value, and the specified turning degree is less than the reference value.
- the slip angle may be selected as the priority to be given.
- the selection means selects one of the vehicle state quantities as a vehicle state quantity to be prioritized in a binary manner using the reference value as a boundary value.
- the yaw rate is selected as the vehicle state quantity to be prioritized when the vehicle is in a turning state
- the slip angle is selected when the vehicle is in a straight traveling state. Therefore, it is possible to reduce the control load while ensuring the effect of the present invention to maintain the optimum vehicle behavior as much as possible.
- the specifying means specifies a rate of change of the turning degree of the vehicle as the turning state quantity (claim 9).
- the rate of change of the turning degree is the time change amount of the turning degree. For example, if the turning degree is the yaw rate, it is the time change amount of the yaw rate.
- the effect of the present invention for maintaining the optimum vehicle behavior as much as possible can be obtained relatively simply by using it alone or in combination with the turning degree as a criterion.
- the selection means selects the yaw rate as the one to be prioritized when the change rate of the specified turning degree is equal to or higher than a reference value, and the change rate of the specified turning degree is When the angle is less than the reference value, the slip angle may be selected as the priority to be given (Claim 10).
- the selection means selects one of the vehicle state quantities as a vehicle state quantity to be prioritized in a binary manner using the reference value as a boundary value.
- the yaw rate is selected as a vehicle state quantity to be prioritized when the vehicle turns sharply, and the slip angle is selected in other cases. Therefore, it is possible to reduce the control load while ensuring the effect of the present invention to maintain the optimum vehicle behavior as much as possible.
- the specifying means specifies the steer characteristic of the vehicle as the turning state quantity (claim 11).
- the steer characteristic of a vehicle is a characteristic of a trajectory with respect to a clearly set or fictitious target travel path. Qualitatively, if the target travel path is traced, it is a neutrast steer. If the actual turning radius is smaller than the target traveling path, it is identified as oversteer, and if the actual turning radius is larger than the target traveling path, it is identified as understeering. Since the vehicle behavior is also different if the steer characteristic is different, this kind of steer characteristic is also useful information for selecting one of the slip angle and the yaw rate or the control ratio thereof.
- the selecting means selects the yaw rate as the one to be prioritized when the specified steer characteristic corresponds to a strong understeer state, and the specified steer state is set to the strong understeer state. If not applicable, the slip angle may be selected as the one to be prioritized (claim 12).
- the strong understeer state is a state in which the running radius of the vehicle is greatly expanded with respect to a clearly set or fictitious target traveling path, and is suitable as a situation where control of the yaw rate should be prioritized.
- Whether or not the steer characteristic corresponds to a strong understeer state can be determined by, for example, arithmetic processing based on the radius and lateral acceleration of the traveling road, or other known methods can be adopted. You can also.
- the vehicle motion control apparatus further includes a stable state quantity specifying means for specifying a stable state quantity that defines a degree of stability of the vehicle behavior, and the selecting means is based on the turning state quantity. Prior to the selection, the one to be prioritized is selected based on the specified stable state quantity (claim 13).
- the stable state quantity that defines the degree of stability of the vehicle behavior is specified.
- the stable state quantity is the vehicle state quantity as in the previous turning state quantity, but whether or not the vehicle behavior is stable at that time, and whether or not the vehicle behavior is easily stabilized.
- it is a state quantity that defines how easy it is to stabilize, etc., it may change with the turning motion, but it itself does not define the turning motion.
- the selection means gives priority to the selection of the vehicle state quantity based on the stable state quantity rather than the selection based on the turning state quantity. Therefore, more importance can be placed on stabilization of the vehicle behavior, and the safety of the vehicle can be improved as much as possible.
- the stable state quantity specifying means specifies the slip angle as the stable state quantity, and the selection means should give priority when the specified slip angle is greater than or equal to a reference value.
- the slip angle may be selected as follows.
- the slip angle is an angle with respect to the turning tangent direction of the vehicle, and is an angle formed by the direction of the vehicle body and the instantaneous traveling direction of the vehicle body, and is thus useful as an index for grasping the degree of stability of the vehicle behavior.
- priority is given to the control of the slip angle as one-degree-of-freedom motion control. Therefore, the vehicle behavior can be maintained in the optimum state as much as possible.
- the stable state amount specifying unit specifies the degree of friction of the traveling road as the stable state amount, and the selecting unit is configured to perform the operation when the specified degree of friction is less than a reference value.
- the slip angle may be selected as one to be prioritized (claim 15).
- the degree of friction on the road in other words, the coefficient of friction, is the stability of the vehicle behavior over the period from now to the near future. Affects the degree of In particular, according to this aspect, when the degree of friction is less than the reference value, priority is given to the control of the slip angle as the motion control with one degree of freedom. Therefore, the vehicle behavior can be maintained in the optimum state as much as possible.
- the target slip angle setting means sets the target slip angle so that the vehicle follows a target travel path
- the target yaw rate setting means includes the vehicle Sets the target yaw rate so as to follow the target travel path
- the behavior control means sets the target slip set so that the slip angle and the yaw rate follow the target travel path, respectively, as the behavior control.
- Trajectory follow-up control for controlling the plurality of devices so as to achieve an angle and a target yaw rate is executed, and the vehicle further includes a steering reaction force control device capable of controlling a steering reaction force, and the vehicle motion control device Is a target steering reaction force setting means for setting a target steering reaction force, which is a target value of the steering reaction force, and the target steering reaction force in which the steering reaction force is set in cooperation with the trajectory tracking control. And further comprising cooperative control execution means for executing cooperative control for controlling the steering reaction force control device, wherein the behavior control means needs to execute behavior control with the one device.
- the trajectory tracking control is continued by controlling the one device so that the selected one has a target value corresponding to the selected one, and the cooperative control execution means performs the trajectory tracking control.
- the cooperative control is continued for a period to be continued (claim 16).
- the target yaw rate and the target slip angle are set for the purpose of tracking control such as LKA, for example. That is, the vehicle can ideally follow the target travel path by controlling the yaw rate and slip angle by the behavior control means.
- a steering reaction force torque represented by, for example, a self-aligning torque of a steering wheel can act on a steering device as a steering input transmission unit for a steering wheel including a steering input unit such as a wheel and a steering mechanism. .
- This steering reaction torque can be said to be a “responsiveness” of the steering if the driver gives a steering force to the steering input means.
- the vehicle movement control for the target vehicle movement is the driver's steering intention. Since this is a kind of automatic steering that can be performed independently of the vehicle (of course, the control itself may be of the nature initiated by the driver's will), such steering reaction torque will give the driver a sense of incongruity easy.
- this steering reaction torque is a reaction torque that tries to rotate the steering input means in the direction opposite to the original turning direction, the steering reaction force torque is not applied when the driver does not give the steering force.
- By turning the input means in the reverse turning direction it is possible to affect the motion control of the vehicle. More specifically, unless some measure is taken, it is difficult to realize automatic steering due to the influence of the reaction torque.
- the vehicle is provided with a steering reaction force control device such as an EPS (Electronic Power Steering) that can control this kind of steering reaction force.
- the steering reaction force control device is controlled so that the steering reaction force becomes a target steering reaction force set by the target steering reaction force setting means (which is a value substantially equivalent to zero if a let-off operation is realized).
- the steering reaction force control device is controlled by the cooperative control execution means so as to cooperate with the trajectory tracking control for the purpose of following the target travel path.
- the steering reaction force control device handles, for example, auxiliary steering torque as a kind of state control amount
- the degree of freedom in vehicle motion control in coordinated control of trajectory tracking control as behavior control and control of this steering reaction force Has three degrees of freedom
- the steering reaction force can be maintained or converged to a desired value (that is, the target steering reaction force).
- the cooperative control is a control that maintains (preferably suppresses to zero) the steering reaction force that is generated in the course of execution of the trajectory tracking control by the yaw rate and slip angle.
- the behavior control unit appropriately changes the state control amount of one device responsible for the trajectory tracking control based on the slip angle or the yaw rate selected by the selection unit, and the trajectory with one degree of freedom.
- the cooperative control means also continues the cooperative control related to the steering reaction force. Therefore, it is possible to maintain the optimum vehicle behavior as much as possible.
- the vehicle condition is set to a permission condition set to permit the termination of the cooperative control in a period in which the cooperative control is continued.
- Permission condition determining means for determining whether or not the condition is satisfied, wherein the behavior control means ends the trajectory tracking control when it is determined that the state of the vehicle satisfies the permission condition, and the cooperative control
- the execution means ends the cooperative control when it is determined that the state of the vehicle corresponds to the permission condition (claim 17).
- the permission condition determination unit determines whether or not the vehicle state meets the permission condition.
- the “permission condition” is a condition that the cooperative control should be terminated, in other words, that the behavior of the vehicle is not destabilized in practice even if the cooperative control is terminated. It refers to a condition that has been determined experimentally, empirically, theoretically, or based on simulation.
- the cooperative control execution means terminates the cooperative control when it is determined that the state of the vehicle meets this permission condition. Accordingly, it is possible to prevent instability of the vehicle behavior that may occur when the cooperative control ends without considering any vehicle behavior at that time.
- the permission condition may include that the vehicle is stopped (claim 18).
- the driver is informed that it is necessary to execute behavior control in one of a plurality of devices via a dedicated or general-purpose various MIL (Multi-Information Lamp) or various function displays.
- MIL Multi-Information Lamp
- FIG. 1 is a schematic configuration diagram conceptually illustrating a configuration of a vehicle according to a first embodiment of the present invention.
- 2 is a flowchart of LKA control performed in the vehicle of FIG. It is a top view of the left front wheel when the driving force is applied.
- 2 is a flowchart of fail-safe control performed in the vehicle of FIG. It is a flowchart of the fail safe control which concerns on 2nd Embodiment of this invention. It is a flowchart of the fail safe control which concerns on 3rd Embodiment of this invention. It is a figure which concerns on 4th Embodiment of this invention and illustrates the relationship between a yaw rate change rate and a yaw rate control selection rate. It is a flowchart of the fail safe control which concerns on 5th Embodiment of this invention.
- FIG. 9 is a schematic diagram of a yaw rate control selectivity map in the failsafe control of FIG. 8.
- FIG. 1 is a schematic configuration diagram conceptually showing the basic configuration of the vehicle 10.
- the vehicle 10 includes a left front wheel FL, a right front wheel FR, a left rear wheel RL, and a right rear wheel RR.
- the steering angle change of the left front wheel FL and the right front wheel FR which are steering wheels, It is configured to be able to travel in a desired direction by changing the steering angle of the left rear wheel FL and the right rear wheel FR.
- the vehicle 10 includes an ECU 100, an engine 200, a driving force distribution device 300, a VGRS actuator 400, an EPS actuator 500, an ECB (Electronic Controlled Braking System) 600, a car navigation device 700, and an ARS actuator 800.
- the ECU 100 is an electronic control unit that includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory) (not shown), and is configured to be able to control the entire operation of the vehicle 10. 1 is an example of a “vehicle motion control device”.
- the ECU 100 is configured to be able to execute LKA control and failsafe control, which will be described later, according to a control program stored in the ROM.
- the ECU 100 includes the “target yaw rate setting means”, “target slip angle setting means”, “behavior control means”, “function restriction state determination means”, “selection means”, “stable state quantity specification means” according to the present invention.
- An integrated electronic control unit configured to function as an example of each of “target steering reaction force setting means”, “cooperative control execution means”, “permission condition determination means”, and “notification means”. All the operations according to the above are executed by the ECU 100.
- the physical, mechanical, and electrical configurations of each of the units according to the present invention are not limited to this.
- each of these units includes a plurality of ECUs, various processing units, various controllers, a microcomputer device, and the like. It may be configured as various computer systems.
- Engine 200 is a power source for vehicle 10.
- the power source of the vehicle according to the present invention is limited to an internal combustion engine (engine 200 is an example thereof) having various practical aspects as a concept encompassing an engine that can take out fuel combustion by converting it into mechanical power.
- a rotating electrical machine such as a motor may be used.
- the vehicle may be a so-called hybrid vehicle in which these are cooperatively controlled.
- a crankshaft that is a driving force output shaft of the engine 200 is connected to a center differential device 310 that is a component of the driving force distribution device. It should be noted that the detailed configuration of the engine 200 has little correlation with the gist of the present invention, and therefore the details are omitted here.
- the driving force distribution device 300 is configured to be able to distribute the engine torque Te transmitted from the engine 200 via the crankshaft to the front wheels and the rear wheels at a predetermined ratio, and further to each of the front wheels and the rear wheels. It is an example of the “braking / driving force variable device” according to the present invention configured to be able to change the driving force distribution of the left and right wheels.
- the driving force distribution device 300 includes a center differential device 310 (hereinafter appropriately referred to as “center differential 310”), a front differential device 320 (hereinafter appropriately referred to as “front differential 320”), and a rear differential device 330 (hereinafter, referred to as “center differential 310”). Appropriately abbreviated as “rear differential 330”).
- the center differential 310 is an LSD (Limited Slip if Differential: differential mechanism with a differential limiting function) that distributes the engine torque Te supplied from the engine 200 to the front differential 320 and the rear differential 330.
- the center differential 310 distributes the engine torque Te to the front and rear wheels at a distribution ratio of 50:50 (an example is not limited) under conditions where the load acting on the front and rear wheels is substantially constant. Further, when the rotational speed of one of the front and rear wheels becomes higher than a predetermined value with respect to the other, a differential limiting torque is applied to the one, and a differential limiting is performed in which torque is transferred to the other. . That is, the center differential 310 is a so-called rotational speed-sensitive (viscous coupling type) differential mechanism.
- the center differential 310 is not limited to such a rotational speed sensitive type, but may be a torque sensitive type differential mechanism in which the differential limiting action increases in proportion to the input torque. Also, a differential ratio variable type differential that can achieve a desired distribution ratio within a predetermined adjustment range by making a differential action by the planetary gear mechanism and continuously changing the differential limiting torque by the intermittent control of the electromagnetic clutch. It may be a mechanism. In any case, the center differential 310 may take various practical aspects regardless of whether it is publicly known or not known as long as the engine torque Te can be distributed to the front wheels and the rear wheels.
- the front differential 320 can distribute the engine torque Te distributed to the front axle (front wheel axle) side by the center differential 310 further to the left and right wheels at a desired distribution ratio set within a predetermined adjustment range.
- the front differential 320 includes a planetary gear mechanism including a ring gear, a sun gear, and a pinion carrier, and an electromagnetic clutch that provides a differential limiting torque.
- a differential case is provided for the ring gear of the planetary gear mechanism, and left and right axles are provided for the sun gear and the carrier, respectively. Takes a linked configuration.
- the differential limiting torque is continuously controlled by energization control on the electromagnetic clutch, and the torque distribution ratio is continuously variably controlled within a predetermined adjustment range determined by the physical and electrical configuration of the front differential 320. It is the composition which becomes.
- the front differential 320 is electrically connected to the ECU 100, and the energization control of the electromagnetic clutch is also controlled by the ECU 100. Therefore, the ECU 100 can generate a desired front wheel left / right braking / driving force difference (here, the driving force difference) F f through the drive control of the front differential 320.
- the configuration of the front differential 320 is limited to that exemplified here as long as the driving force (note that the torque and the driving force are uniquely related) can be distributed to the left and right wheels at a desired distribution ratio. It can have various aspects regardless of whether it is publicly known or not known. In any case, such a right / left driving force distribution action is known, and here, the details thereof will not be mentioned for the purpose of preventing the explanation from becoming complicated.
- the rear differential 330 distributes the engine torque Te distributed to the rear axle (rear axle) via the propeller shaft 11 by the center differential 310, and further at a desired distribution ratio set within a predetermined adjustment range for the left and right wheels.
- This is a variable distribution ratio LSD that can be distributed.
- the rear differential 330 includes a planetary gear mechanism including a ring gear, a sun gear, and a pinion carrier, and an electromagnetic clutch that provides differential limiting torque.
- a differential case is connected to the ring gear of the planetary gear mechanism, and left and right axles are connected to the sun gear and the carrier, respectively.
- Adopted configuration The differential limiting torque is continuously controlled by energization control for the electromagnetic clutch, and the torque distribution ratio is continuously variably controlled within a predetermined adjustment range determined by the physical and electrical configuration of the rear differential 330. It has a configuration.
- the rear differential 330 is electrically connected to the ECU 100, and the energization control of the electromagnetic clutch is also controlled by the ECU 100. Therefore, ECU 100, via the drive control of the rear differential 330, (here, a is the driving force difference) desired rear wheel left and right longitudinal force difference it is possible to cause F r.
- the configuration of the rear differential 330 is limited to that illustrated here as long as the driving force (where torque and driving force are uniquely related) can be distributed to the left and right wheels at a desired distribution ratio. It can have various aspects regardless of whether it is publicly known or not. In any case, such a right / left driving force distribution action is known, and here, the details thereof will not be mentioned for the purpose of preventing the explanation from becoming complicated.
- the VGRS actuator 400 is a steering transmission ratio variable device including a housing, a VGRS motor, a speed reduction mechanism, a lock mechanism (all not shown), and the like, and is an example of the “front wheel steering angle variable device” according to the present invention.
- the VGRS actuator 400 In the VGRS actuator 400, the VGRS motor, the speed reduction mechanism, and the lock mechanism are accommodated in the housing.
- This housing is fixed to the downstream end portion of the upper steering shaft 13 connected to the steering wheel 12 as steering input means, and is configured to be rotatable substantially integrally with the upper steering shaft 13.
- the VGRS motor is a DC brushless motor having a rotor that is a rotor, a stator that is a stator, and a rotating shaft that is an output shaft of driving force.
- the stator is fixed inside the housing, and the rotor is rotatably held inside the housing.
- the rotating shaft is fixed so as to be coaxially rotatable with the rotor, and the downstream end thereof is connected to the speed reduction mechanism.
- the stator is configured to be supplied with a drive voltage from an electric drive circuit (not shown).
- the speed reduction mechanism is a planetary gear mechanism having a plurality of rotational elements capable of differential rotation.
- One rotation element of the plurality of rotation elements is connected to the rotation shaft of the VGRS motor, and one of the other rotation elements is connected to the housing. The remaining rotating elements are connected to the lower steering shaft 14.
- the rotation speed of the upper steering shaft 13 (that is, the rotation speed of the housing) corresponding to the operation amount of the steering wheel 12 and the rotation speed of the VGRS motor (that is, the rotation of the rotation shaft).
- Speed uniquely determines the rotation speed of the lower steering shaft 14 connected to the remaining one rotation element.
- the rotational speed of the lower steering shaft 14 can be controlled to increase / decrease by controlling the rotational speed of the VGRS motor to increase / decrease by the differential action between the rotating elements. That is, the upper steering shaft 13 and the lower steering shaft 14 can be rotated relative to each other by the action of the VGRS motor and the speed reduction mechanism.
- the rotational speed of the VGRS motor is transmitted to the lower steering shaft 14 in a state of being decelerated in accordance with a predetermined reduction ratio determined according to the gear ratio between the respective rotary elements because of the configuration of each rotary element in the speed reduction mechanism.
- the upper steering shaft 13 and the lower steering shaft 14 can rotate relative to each other, so that the steering angle ⁇ MA that is the amount of rotation of the upper steering shaft 13 and the amount of rotation of the lower steering shaft 14 are determined.
- the steering transmission ratio which is uniquely determined (which also relates to the gear ratio of the rack and pinion mechanism described later) and the steering angle ⁇ f of the front wheel as the steering wheel, is continuously variable within a predetermined range.
- the lock mechanism is a clutch mechanism including a clutch element on the VGRS motor side and a clutch element on the housing side.
- a clutch mechanism including a clutch element on the VGRS motor side and a clutch element on the housing side.
- VGRS actuator 400 is electrically connected to the ECU 100 and its operation is controlled by the ECU 100.
- the rack and pinion mechanism is a steering transmission mechanism including a pinion gear (not shown) connected to the downstream end of the lower steering shaft 14 and a rack bar 15 formed with gear teeth that mesh with gear teeth of the pinion gear.
- the rotation of the pinion gear is converted into the horizontal movement of the rack bar 15 in the drawing, so that the steering force is applied to each steered wheel via a tie rod and a knuckle (not shown) connected to both ends of the rack bar 15. It is configured to be transmitted. That is, the transmission mechanism of the steering force from the steering wheel 12 to each front wheel is an example of the “steering device” according to the present invention.
- the EPS actuator 500 includes an EPS motor as a DC brushless motor including a rotor (not shown) that is a rotor to which a permanent magnet is attached and a stator that is a stator that surrounds the rotor. It is a steering torque auxiliary device as an example of “reaction force control means”.
- This EPS motor can generate EPS torque T eps in its rotating direction by rotating the rotor by the action of a rotating magnetic field formed in the EPS motor by energizing the stator via an electric drive (not shown). It is configured.
- a reduction gear (not shown) is fixed to the motor shaft which is the rotation shaft of the EPS motor, and this reduction gear meshes directly or indirectly with the reduction gear provided on the lower steering shaft 14. ing.
- the EPS torque T eps generated from the EPS motor functions as a torque that assists the rotation of the lower steering shaft 14. Therefore, when the EPS torque T eps is applied in the same direction as the driver steering torque MT applied to the upper steering shaft 13 via the steering wheel 12, the driver's steering burden is equal to the EPS torque T eps . It is reduced.
- the EPS actuator 500 is a so-called electronically controlled power steering device that is electrically connected to the ECU 100 and assists the driver steering torque by the torque of a motor whose operation is controlled by the ECU 100.
- the steering device may be a so-called hydraulic power steering device that reduces a driver's steering load by a hydraulic driving force applied via the hydraulic driving device.
- VGRS actuator 400 and the EPS actuator 500 may be configured as an actuator integrated with each other.
- the vehicle 10 includes a steering angle sensor 16 and a steering torque sensor 17.
- the steering angle sensor 16 is an angle sensor configured to be able to detect a steering angle ⁇ MA that represents the amount of rotation of the upper steering shaft 13.
- Steering angle sensor 16 is connected to ECU 100 and electrically, the detected steering angle [delta] MA is adapted configuration as referenced in constant or irregular period by the ECU 100.
- the steering torque sensor 17 is a sensor configured to be able to detect a driver steering torque MT given from the driver via the steering wheel 12. More specifically, the upper steering shaft 13 is divided into an upstream portion and a downstream portion, and has a configuration in which they are connected to each other by a torsion bar (not shown). Rings for detecting a rotational phase difference are fixed to both upstream and downstream ends of the torsion bar. This torsion bar is twisted in the rotational direction according to the steering torque (ie, driver steering torque MT) transmitted through the upstream portion of the upper steering shaft 13 when the driver of the vehicle 10 operates the steering wheel 12. The configuration is such that the steering torque can be transmitted to the downstream portion while causing such a twist.
- the steering torque sensor 17 is configured to detect such a rotational phase difference and convert the rotational phase difference into a steering torque so as to be output as an electrical signal corresponding to the driver steering torque MT.
- the steering torque sensor 17 is electrically connected to the ECU 100, and the detected driver steering torque MT is referred to by the ECU 100 at a constant or indefinite period.
- the steering torque detection method is not limited to this type of torsion bar method, and other methods may be adopted.
- a configuration in which a torque sensor is incorporated in the EPS actuator 500 is also common, and when the driver steering torque MT is specified, the detected value of the torque sensor is used or estimated based on the detected value of the torque sensor.
- a technique such as performing may be employed.
- the steering torque sensor 17 configured separately from the EPS actuator 500 is not necessarily mounted.
- the ECB 600 is an electronically controlled braking device as another example of the “braking / driving force varying means” according to the present invention, which is configured to be able to individually apply a braking force to the front, rear, left, and right wheels of the vehicle 10.
- the ECB 600 includes a brake actuator 610 and braking devices 620FL, 620FR, 620RL, and 620RR corresponding to the left front wheel FL, the right front wheel FR, the left rear wheel RL, and the right rear wheel RR, respectively.
- the brake actuator 610 is a hydraulic control actuator configured to be able to individually supply hydraulic oil to the braking devices 620FL, 620FR, 620RL, and 620RR.
- the brake actuator 610 includes a master cylinder, an electric oil pump, a plurality of hydraulic pressure transmission passages, and electromagnetic valves installed in each of the hydraulic pressure transmission passages.
- the hydraulic pressure of the hydraulic oil supplied to the wheel cylinder provided in the device is configured to be individually controllable for each braking device.
- the hydraulic pressure of the hydraulic oil has a one-to-one relationship with the pressing force of the brake pad provided in each brake device, and the hydraulic oil pressure level of the hydraulic oil corresponds to the magnitude of the braking force in each brake device.
- the brake actuator 610 is electrically connected to the ECU 100, and the braking force applied to each wheel from each braking device is controlled by the ECU 100.
- the vehicle 10 includes an in-vehicle camera 18 and a vehicle speed sensor 19.
- the in-vehicle camera 18 is an imaging device that is installed on the front nose of the vehicle 10 and configured to image a predetermined area in front of the vehicle 10.
- the in-vehicle camera 18 is electrically connected to the ECU 100, and the captured front area is sent to the ECU 100 as image data at a constant or indefinite period.
- the ECU 100 can analyze the image data and acquire various data necessary for LKA control described later.
- the vehicle speed sensor 19 is a sensor configured to be able to detect the vehicle speed V, which is the speed of the vehicle 10.
- the vehicle speed sensor 19 is electrically connected to the ECU 100, and the detected vehicle speed V is referred to by the ECU 100 at a constant or indefinite period.
- the car navigation device 700 is based on signals acquired via a GPS antenna and a VICS antenna installed in the vehicle 10, position information of the vehicle 10, road information around the vehicle 10 (road type, road width, number of lanes). , Speed limit, road shape, etc.), traffic signal information, information on various facilities installed around the vehicle 10, traffic information including traffic information, environment information, and the like.
- the car navigation device 700 is electrically connected to the ECU 100, and the operation state is controlled by the ECU 100.
- ARS actuator 800 capable of a wheel steering angle [delta] r after a steering angle of the left rear wheel RL and the right rear wheel RR, vary independently of the steering input by the driver via the steering wheel 12 gives, 1 is a rear wheel steering actuator which is an example of a “rear wheel steering angle varying device” according to the present invention.
- the ARS actuator 800 includes an ARS motor and a reduction gear mechanism, and a drive circuit for the ARS motor is electrically connected to the ECU 100. Therefore, the ECU 100 can control the ARS torque Tars , which is the output torque of the ARS motor, by controlling the drive circuit.
- the reduction gear is configured to be able to transmit the torque of the ARS motor to the rear steer rod 20 with deceleration.
- Rear steering rod 20, and a left rear wheel RL and the right rear wheel RR, are connected via the respective joint members 21RL and 21RR, the rear steering rod 20 is driven to the illustrated right direction by ARS torque T ars, each The rear wheels are steered in one direction.
- the ARS actuator 800 may include a linear motion mechanism that can convert a rotational motion into a stroke motion.
- the rear steer rod 20 may change the rudder angle of the rear wheels in accordance with the left-right stroke motion of the linear motion mechanism.
- the practical aspect of the rear wheel steering device is not limited to that of the illustrated ARS actuator 800 as long as the rear wheel steering angle ⁇ r can be varied within a predetermined range.
- the vehicle 10 further includes a yaw rate sensor 22 and a slip angle sensor 23.
- the yaw rate sensor 22 is a sensor configured to be able to detect the yaw rate ⁇ of the vehicle 10.
- the yaw rate sensor 22 is electrically connected to the ECU 100, and the detected yaw rate ⁇ is referred to by the ECU 100 at a constant or indefinite period.
- the slip angle sensor 23 is a sensor configured to be able to detect the slip angle ⁇ of the vehicle 10.
- the slip angle sensor 23 is electrically connected to the ECU 100, and the detected slip angle ⁇ is referred to by the ECU 100 at a constant or indefinite period.
- the vehicle body slip angle ⁇ is based on a calculation algorithm set in advance from various state control amounts (for example, the steering angle of each wheel or a value corresponding to the steering angle) and various vehicle state amounts (for example, the yaw rate ⁇ and the vehicle speed V).
- state control amounts for example, the steering angle of each wheel or a value corresponding to the steering angle
- vehicle state amounts for example, the yaw rate ⁇ and the vehicle speed V.
- the configuration may be estimated as described above.
- the vehicle 10 according to the present embodiment has a difference in the left and right braking / driving force between the front and rear wheels in addition to the VGRS actuator 400 and the ARS actuator 800 for controlling the steering angle of the front and rear wheels independently from the steering input from the driver side.
- a driving force distribution device 300 that can change the yaw rate ⁇ or slip angle ⁇ and the steering reaction torque T in the fail-safe control described later.
- the vehicle according to the present invention may have a vehicle configuration in which the driving force distribution device 300 does not exist in the case of the vehicle 10. If it supplements, the structure which does not have this kind of driving force distribution device is overwhelmingly advantageous from the viewpoint of cost, the weight of the vehicle, and the space of the installation, and the vehicle according to the present invention. As a preferred form, only the front and rear wheel steering angle variable device is mounted. Even in a configuration that does not include a driving force distribution device, fail-safe control described later can be executed without any problem in practice.
- ⁇ 1-2-1 Details of LKA control>
- FIG. 2 Details of LKA control>
- the steering reaction force torque control that maintains the steering reaction force torque T at the target steering reaction force torque, and the vehicle 10 is made to follow the target travel path (in this embodiment, that is, the lane (lane)).
- This is one of the driving support controls executed in the vehicle 10 by adopting a cooperative control mode in which the tracking control is coordinated.
- the ECU 100 reads various signals including operation signals of various switches provided in the vehicle 10, various flags, sensor signals related to the various sensors, and the like (step S ⁇ b> 101) and is installed in the vehicle interior of the vehicle 10 in advance. It is determined whether or not the LKA mode is selected as a result of the operation button for activating the LKA mode being operated by the driver (step S102). When the LKA mode is not selected (step S102: NO), the ECU 100 returns the process to step S101.
- step S102 When the LKA mode is selected (step S102: YES), the ECU 100 detects a white line (not necessarily white) that defines the LKA target travel path based on the image data sent from the in-vehicle camera 18. It is determined whether or not it has been performed (step S103).
- a white line not necessarily white
- step S103 If no white line is detected (step S103: NO), the ECU 100 returns the process to step S101 because a virtual target travel path cannot be set. On the other hand, when the white line is detected (step S103: YES), the ECU 100 calculates various road surface information necessary for causing the vehicle 10 to follow the target travel path (step S104).
- step S104 a lateral deviation Y that is a lateral deviation between the white line and the vehicle 10, a yaw angle deviation ⁇ between the white line and the vehicle 10, and a travel path radius R are calculated based on a known method.
- Step S105 is an example of the operation of the “target yaw rate setting means” according to the present invention.
- the target yaw rate ⁇ tg is stored in advance in an appropriate storage means such as a ROM so as to be associated with the lateral deviation Y and the yaw angle deviation ⁇ , and the ECU 100 calculates each of the values calculated in step S104.
- the target yaw rate ⁇ tg is set by appropriately selecting a corresponding value according to the road surface information.
- various modes can be applied regardless of whether the target yaw rate ⁇ tg is set.
- Step S106 is an example of the operation of the “target slip angle setting means” according to the present invention.
- the target slip angle ⁇ tg is stored in advance in an appropriate storage means such as a ROM in a manner corresponding to the lateral deviation Y, yaw angle deviation ⁇ , and travel path radius R.
- the target slip angle ⁇ tg is set by selecting an appropriate value according to each road surface information calculated in S104.
- various modes can be applied regardless of whether the target slip angle ⁇ tg is set.
- Step S107 is an example of the operation of the “target steering reaction force setting means” according to the present invention.
- the target steering reaction torque T tg is a torque that acts on the steering device from the front wheels that are the steering wheels when the vehicle 10 follows the target travel path, and is an example of the “steering reaction force” according to the present invention.
- the target steering reaction torque T tg is zero. That the steering reaction torque T tg is zero means that it is not necessary to give a steering torque to the steering wheel 12 when the vehicle 10 follows the target travel path, and it is possible to run by hand. It means that there is.
- the ECU 100 uses the target values of the front wheel steering angle ⁇ f , the rear wheel steering angle ⁇ r, and the EPS torque T eps for realizing the target values of the vehicle state quantities calculated or set in steps S105 to S107.
- a certain target front wheel steering angle, target rear wheel steering angle, and target EPS torque are calculated (step S108).
- a detailed method for determining the target front wheel steering angle, the target rear wheel steering angle, and the target EPS torque will be described later.
- the ECU 100 preliminarily calculates the yaw rate ⁇ , the slip angle ⁇ , the steering reaction torque T, the front wheel steering angle, Based on the vehicle motion model set to define the relative relationship between the rear wheel rudder angle and the EPS torque, the yaw rate ⁇ , the slip angle ⁇ , and the steering reaction torque T are respectively set to the target yaw rate ⁇ tg , the target slip angle ⁇ tg, and Target values of the front wheel steering angle ⁇ f , the rear wheel steering angle ⁇ r and the EPS torque T eps for setting the target steering reaction torque T tg (that is, the target front wheel steering angle, the target rear wheel steering angle, and the target EPS torque, respectively). To decide.
- the ECU 100 determines whether or not there is an override operation by the driver (step S109).
- the override operation is a steering operation that the driver performs by his / her own intention, that is, one of the steering inputs that should be given the highest priority in vehicle operation control.
- the ECU 100 refers to the sensor outputs of the steering angle sensor 16 and the steering torque sensor 17 to determine whether or not an override operation is performed, and the steering angle ⁇ MA is greater than or equal to the reference value ⁇ MAth or the driver steering torque MT is the reference value. When it is equal to or greater than MTth, it is determined that an override operation has occurred.
- step S109 When it is determined that the override operation has occurred (step S109: YES), the ECU 100 ends the LKA mode (step S110). When the LKA mode ends, the process returns to step S101, and a series of processes is repeated.
- step S109 NO
- the ECU 100 causes the VGRS actuator 400, the target front wheel steering angle, the target rear wheel steering angle, and the target EPS torque calculated in step S108 to be obtained.
- the ARS actuator 800 and the EPS actuator 500 are controlled (step S111).
- step S111 the process returns to step S103, and a series of operations in the LKA mode is repeated.
- the LKA control is executed as described above.
- FIG. 3 is a top view of the left front wheel FL when the driving force is applied.
- the same reference numerals are given to the same portions as those in FIG. 1, and the description thereof will be omitted as appropriate.
- the ground point C of the front left wheel FL driving force F d is acting.
- the virtual grounding point KP of the kingpin shaft which is a virtual steering axis connecting the upper pole joint and the lower pole joint
- the yaw moment is generated in the left front wheel FL according to the kingpin offset k which is the distance between this axis and the virtual grounding point KP.
- the generation direction of the yaw moment in this case is the right turn direction.
- Such a yaw moment can occur in the same manner when a braking force is applied instead of the driving force.
- the braking force is a negative driving force, and when a braking force difference occurs between the left and right wheels, a yaw moment is generated on the side of the wheel having a large braking force.
- turning behavior can be given to the vehicle 10 by giving a left / right braking / driving force difference to at least one of the front wheels and the rear wheels.
- the left front wheel FL When a tire slip angle is generated in the left front wheel FL by steering or turning or both (that is, when a deviation occurs between the direction of the center line of the tire and the traveling direction of the tire), the left front wheel FL is A tire lateral force Yf is generated in the leftward direction at the force application point on the rear side of the contact point.
- Distance t of the force application point and the virtual ground point KP is the distance between the force application point of the caster trail is axial distance between the virtual ground point KP and the tire ground contact point C, the tire ground contact point C and the lateral force Y f It means the sum with a certain pneumatic trail.
- step S108 in the LKA control that is, the determination of the target front wheel steering angle, the target rear wheel steering angle, and the target EPS torque based on the vehicle motion model will be described.
- the meanings represented by the respective reference symbols in the following formulas described later will be added in advance.
- the matrix A is expressed by the following equation (8).
- matrix coefficients A11, A12, A13, A21, A22, A23, A31, A32, and A33 of the matrix A are expressed by the following equations (10) to (18), respectively.
- matrix coefficients B11, B12, B13, B21, B22, B23, B31, B32 and B33 of the matrix B are expressed by the following equations (19) to (27), respectively.
- the fail safe control is a control that the ECU 100 always executes during the execution period of the LKA control, and the control content of the fail safe control is configured to have priority over the LKA control.
- the ECU 100 determines the functional states of the VGRS actuator 400 and the ARS actuator 800, and determines whether they are in a function restriction state (step S201).
- the “function restriction state” means a state in which at least one of the actuators has failed, or a state in which the function is significantly restricted due to some situation. More specifically, a state in which the motor of each actuator is not operating normally, a state in which operation is limited by a thermal load, a state in which the operation speed of each actuator is not sufficiently secured by the control load of the ECU 100, etc. means. It should be noted that a detailed mode relating to the determination of whether or not each actuator is in a function-restricted state is omitted here because various known failure detection controls can be applied. As a result of the determination, if both of these are in a normal state that is not in the function restriction state (step S201: NO), the process enters a standby state in step S201.
- step S201 when at least one actuator is in the function restriction state (step S201: YES), the ECU 100 selects a control device (step S202).
- the state control amount that maintains controllability in the LKA control is only the EPS torque T eps , or one of the front wheel steering angle ⁇ f and the rear wheel steering angle ⁇ r Therefore, the slip angle ⁇ and the yaw rate ⁇ cannot be controlled independently in the LKA control. Therefore, it is necessary to select the remaining device that is not in the function-restricted state and control one of the slip angle ⁇ and the yaw rate ⁇ .
- step S202 the ECU 100 selects the ARS actuator 800 as a control device when the VGRS actuator 400 is in a function restriction state, and selects the VGRS actuator 400 as a control device when the ARS actuator 800 is in a function restriction state.
- the driving force distribution device 300 is selected as the control device.
- the ECU 100 determines whether or not the vehicle behavior is stable based on the slip angle ⁇ and the road surface friction coefficient ⁇ (that is, an example of the “stabilized state quantity” according to the present invention). (Step S203). More specifically, it is determined whether or not the slip angle ⁇ is less than the reference value ⁇ th and the road surface friction coefficient ⁇ is greater than or equal to the reference value ⁇ th .
- step S203 When the vehicle behavior is not stable (step S203: NO), the ECU 100 unconditionally selects the slip angle ⁇ as a control target, and the EPS torque T Eps and the state control amount (front wheel) corresponding to the previously selected control device. Based on the steering angle ⁇ f , the rear wheel steering angle ⁇ r , the front wheel left / right braking / driving force difference F f or the rear wheel left / right braking / driving force difference F r ), the steering reaction torque T and the slip angle ⁇ are controlled (step) S206). On the other hand, when the vehicle behavior is stable (step S203: YES), the ECU 100 further determines whether or not the vehicle 10 is turning (step S204).
- step S204 it is determined whether the yaw rate ⁇ is greater than or equal to a reference value ⁇ th . If the vehicle 10 is not turning (step S204: NO), the ECU 100 determines that the necessity for positively controlling the yaw rate ⁇ is low, and shifts the processing to step S206.
- step S204 When it is determined in step S204 that the vehicle 10 is turning (step S204: YES), the ECU 100 selects the yaw rate ⁇ as the control target, and corresponds to the EPS torque T eps and the previously selected control device. Steering reaction force torque T and yaw rate ⁇ based on the state control amount (front wheel steering angle ⁇ f , rear wheel steering angle ⁇ r , front wheel left / right braking / driving force difference F f or rear wheel left / right braking / driving force difference F r ). Is controlled (step S205). The actual control mode in step S205 and step S206 will be described later.
- step S205 or step S206 the process proceeds to step S207, and whether or not the LKA control may be terminated, that is, whether or not the state of the vehicle 10 satisfies the permission condition according to the present invention. Determined.
- the condition is that the vehicle 10 is in a stopped state. If the vehicle 10 has not yet stopped (step S207: NO), the ECU 100 returns the process to step S201 and repeats the processes so far.
- step S202 the control device is reselected.
- step S207 YES
- the ECU 100 determines that at least one of the VGRS actuator 400 and the ARS actuator 800 is in a function restricted state.
- the driver is notified through information display via a display device provided in the device 700, lighting control of various information lamps in the meter hood, or the like (step S208).
- the LKA control in this case, the alternative LKA control in which controllability is imparted to only one of the slip angle ⁇ and the yaw rate ⁇
- step S209 the LKA control (in this case, the alternative LKA control in which controllability is imparted to only one of the slip angle ⁇ and the yaw rate ⁇ ) is ended (step S209).
- the trajectory tracking control that is executed in cooperation with the control of the steering reaction torque T in the LKA control is performed at least among the VGRS actuator 400 and the ARS actuator 800.
- the trajectory tracking control as a two-degree-of-freedom motion control originally realized by independently controlling the slip angle ⁇ and the yaw rate ⁇ is the slip angle. It is changed to one-degree-of-freedom trajectory tracking control consisting of one control of ⁇ or yaw rate ⁇ and continued.
- the vehicle state quantity to be prioritized is selected based on the stability level of the vehicle behavior at that time and the turning behavior of the vehicle, and one of them is selected according to the vehicle behavior at that time Is done. That is, when the vehicle behavior is unstable (in this case, the slip angle is large or the road surface friction coefficient is large), the slip angle ⁇ is positive, and if the vehicle is turning while the vehicle behavior is stable, it is positive. Therefore, when there is no reason to prioritize the yaw rate ⁇ , the slip angle ⁇ that can lead the vehicle behavior to a more stable side is selected by the elimination method.
- FIG. 5 is a flowchart of the failsafe control according to the second embodiment.
- the same reference numerals are given to the same portions as those in FIG. 4, and the description thereof will be omitted as appropriate.
- step S301 the ECU 100 determines whether or not the turning degree change rate is further large (step S301). More specifically, it is determined whether or not the rate of change ⁇ of the yaw rate ⁇ is greater than or equal to the reference value ⁇ th .
- step S301: NO the ECU 100 proceeds to step S206 to select the slip angle ⁇ as the vehicle state quantity, while when the turning degree change rate is large (step S301). : YES), the ECU 100 shifts the processing to step S205 and selects the yaw rate ⁇ as the vehicle state quantity.
- the rate of change in the degree of turning is particularly large in the early stage of turning, for example, in emergency avoidance traveling (for example, traveling that avoids a front obstacle) in which an abrupt turning operation is performed.
- emergency avoidance traveling for example, traveling that avoids a front obstacle
- the yaw rate ⁇ can be selected with a more rational reason in part of the conditions for selecting the slip angle ⁇ for the negative reason in the first embodiment. Therefore, it is possible to make the vehicle behavior more stable in accordance with the actual situation.
- FIG. 6 is a flowchart of the failsafe control according to the third embodiment. In the figure, the same reference numerals are given to the same portions as those in FIG. 4, and the description thereof will be omitted as appropriate.
- step S204 when the vehicle behavior is stable and the vehicle 10 is not turning (step S204: NO), the ECU 100 further determines whether or not the steering state of the vehicle 10 is a strong understeer (step S204). S401). More specifically, it is determined whether or not the degree to which the vehicle 10 is swollen outward with respect to the target travel path in the trajectory tracking control is equal to or greater than a reference value. Such a determination can be made based on the yaw angle deviation ⁇ calculated in step S104 in the LKA control, the travel path radius R, and the like.
- step S401: NO When the steering characteristic of the vehicle 10 is an oversteer characteristic, a neutral steer characteristic, or a weak understeer characteristic (step S401: NO), the ECU 100 proceeds to step S206 while selecting the slip angle ⁇ as the vehicle state quantity.
- step S401: YES When the steering characteristic is the strong understeer characteristic (step S401: YES), the ECU 100 shifts the process to step S205 and selects the yaw rate ⁇ as the vehicle state quantity.
- the yaw rate ⁇ is greater than the slip angle ⁇ .
- the yaw rate ⁇ can be selected with a more rational reason in part of the conditions for selecting the slip angle ⁇ for the negative reason in the first embodiment. Therefore, it is possible to make the vehicle behavior more stable in accordance with the actual situation.
- FIG. 7 is a diagram illustrating the relationship between the yaw rate change rate ⁇ and the yaw rate control selection rate.
- the yaw rate control selectivity means the selection ratio between the yaw rate ⁇ and the slip angle ⁇ .
- the yaw rate control selectivity is “0” in the region of ⁇ ⁇ 1
- the yaw rate control selectivity is “1” in the region of ⁇ ⁇ ⁇ 2.
- the yaw rate control selectivity increases linearly according to ⁇ .
- this yaw rate control selection rate is used as a value that defines the selection frequency when there are multiple selection opportunities.
- step S301 can be replaced with a step of determining a control ratio according to the relationship of FIG.
- the yaw rate control selectivity is 0.5
- the slip angle ⁇ is selected at a rate of once every two times.
- step S501 when a control device is selected (step S202), the ECU 100 determines a yaw rate control selection rate Kyr (step S501).
- the yaw rate control selectivity Kyr is equivalent to the yaw rate control selectivity described in the fourth embodiment, but the determination mode is different in this embodiment. That is, in step S501, the ECU 100 determines the yaw rate control selectivity Kyr by referring to the yaw rate control selectivity map stored in the ROM in advance using the yaw rate ⁇ and the slip angle ⁇ as parameters.
- FIG. 9 is a schematic diagram of a yaw rate control selectivity map.
- the yaw rate control selectivity Kyr is defined by a two-dimensional map having the slip angle ⁇ and the yaw rate ⁇ as the vertical axis and the horizontal axis, respectively.
- the ECU 100 can determine the yaw rate control selectivity Kyr by selecting one yaw rate control selectivity Kyr corresponding to the current yaw rate ⁇ and slip angle ⁇ . It goes without saying that the relationship illustrated in FIG. 9 is digitized and stored in the ROM.
- step S502 when the yaw rate control selection rate Kyr is determined, the ECU 100 appropriately selects and controls the yaw rate ⁇ or the slip angle ⁇ based on the determined Kyr (step S502).
- step S502 the process proceeds to step S207.
- the yaw rate control selectivity Kyr can be determined based on more parameters, and finer vehicle behavior control is possible.
- ⁇ 6 Control of vehicle state quantity in trajectory tracking control with one degree of freedom>
- a control mode for example, FIG. 4 of the slip angle ⁇ or the yaw rate ⁇ and the steering reaction force torque T according to the control device (state control amount) selected in step S202. S205 and S206) will be described. Note that this control mode uses a vehicle handling model based on the vehicle motion equation, as in step S108 of LKA control. Below, the relationship between a state control amount and a vehicle state quantity is demonstrated for every combination of a control device and a vehicle state quantity. There are eight types of combinations (A) to (G) below.
- Equation (30) the matrix C is expressed as the following equation (30). Note that det (A) represents the matrix A.
- matrix coefficients C11, C12, C21, and C22 of the matrix C are expressed as the following equations (31) to (34), respectively.
- the matrix coefficients D11, D12, D21, and D22 of the matrix D are expressed as the following equations (38) to (41), respectively.
- matrix coefficients E11, E12, E21, and E22 of the matrix E are expressed as the following equations (45) to (48), respectively.
- matrix coefficients F11, F12, F21, and F22 of the matrix F are represented by the following equations (52) to (55), respectively.
- the matrix coefficients G11, G12, G21, and G22 of the matrix G are expressed as the following equations (59) to (62), respectively.
- matrix coefficients H11, H12, H21, and H22 of the matrix H are expressed as the following equations (66) to (69), respectively.
- matrix coefficients J11, J12, J21, and J22 of the matrix J are expressed as the following equations (73) to (76), respectively.
- matrix coefficients K11, K12, K21, and K22 of the matrix K are expressed as the following equations (80) to (83), respectively.
- the vehicle motion can be suitably controlled by the drive control of the EPS actuator 500 and the selected device (VGRS actuator 300, ARS actuator 800, or driving force distribution device 300).
- the “tracking tracking control when the VGRS actuator 300 and / or the ARS actuator 800 or both are in the function-restricted state” is assumed as “when it is necessary to execute behavior control with one apparatus” according to the present invention.
- the need to execute behavior control in one apparatus is not limited to such a function restriction state, and may occur for various reasons.
- the present invention defines a control method for optimally maintaining the vehicle behavior when such a need arises, and the reason why such a need arises depends on its effectiveness. It has no effect.
- the present invention is not limited to the above-described embodiments, and can be appropriately changed without departing from the gist or concept of the invention that can be read from the claims and the entire specification.
- the apparatus is also included in the technical scope of the present invention.
- the present invention can be used for, for example, a vehicle having a function of causing the vehicle to follow a target travel path.
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Abstract
Description
以下、適宜図面を参照して本発明の車両の制御装置に係る各種実施形態について説明する。
<1:第1実施形態>
<1-1:実施形態の構成>
始めに、図1を参照して、本発明の第1実施形態に係る車両10の構成について説明する。ここに、図1は、車両10の基本的な構成を概念的に表してなる概略構成図である。
<1-2:実施形態の動作>
<1-2-1:LKA制御の詳細>
以下、図2を参照し、本実施形態の動作として、ECU100により実行されるLKA制御の詳細について説明する。ここに、図2は、LKA制御のフローチャートである。尚、LKA制御は、操舵反力トルクTを目標操舵反力トルクに維持する操舵反力トルク制御と、車両10を目標走行路(本実施形態では、即ち車線(レーン)である)に追従させる軌跡追従制御とを協調させる協調制御の態様を採り、車両10において実行される走行支援制御の一つである。
<1-2-2:左右制駆動力差によるヨーモーメントの発生>
ここで、図3を参照し、車輪に作用する制駆動力とヨーモーメントとの関係について説明する。図3は、駆動力が作用した場合の左前車輪FLの上面視図である。尚、同図において、図1と重複する箇所には同一の符合を付してその説明を適宜省略することとする。
<1-2-3:車両運動モデルに基づいた目標前輪舵角、目標後輪舵角及び目標EPSトルクの決定方法>
次に、LKA制御におけるステップS108の動作、即ち、車両運動モデルに基づいた目標前輪舵角、目標後輪舵角及び目標EPSトルクの決定について説明する。尚、予め後述する下記各式における各参照記号の表す意味を付記しておく。
δf・・・前輪操舵角
δr・・・後輪操舵角
β・・・スリップ角
γ・・・ヨーレート
T・・・操舵反力トルク(本実施形態では、キングピン軸回りのトルク)
V・・・車速
Mf・・・前軸質量
Mr・・・後軸質量
M・・・車両質量(M=Mf+Mr)
I・・・ヨーイング慣性モーメント
L・・・ホイールベース
Lf・・・車両重心から前軸までの前後方向距離
Lr・・・車両重心から後軸までの前後方向距離
Kf・・・前輪コーナリングパワー
Kr・・・後輪コーナリングパワー
Tf・・・前軸トレッド
Tr・・・後軸トレッド
t・・・前後方向トレール量
k・・・キングピンオフセット
Yf・・・前輪横力
Yr・・・後輪横力
Ffl・・・左前輪駆動力
Ffr・・・右前輪駆動力
Frl・・・左後輪駆動力
Frr・・・右後輪駆動力
Ff・・・前輪左右制駆動力差
Fr・・・後輪左右制駆動力差
前輪舵角δf、後輪舵角δr及びEPSトルクTepsは、下記(1)式乃至(5)式により表される車両運動方程式をスリップ角β、ヨーレートγ及び操舵反力トルクTについて解いて得られる下記(6)式から、最終的に下記(7)式により表される。
<1-2-4:フェールセーフ制御の詳細>
次に、図4を参照し、フェールセーフ制御の詳細について説明する。ここに、図4は、フェールセーフ制御のフローチャートである。
<2:第2実施形態>
次に、図5を参照し、本発明の第2実施形態に係るフェールセーフ制御について説明する。ここに、図5は、第2実施形態に係るフェールセーフ制御のフローチャートである。尚、同図において、図4と重複する箇所には同一の符号を付してその説明を適宜省略することとする。
<3:第3実施形態>
次に、図6を参照し、本発明の第3実施形態に係るフェールセーフ制御について説明する。ここに、図6は、第3実施形態に係るフェールセーフ制御のフローチャートである。尚、同図において、図4と重複する箇所には同一の符号を付してその説明を適宜省略することとする。
<4:第4実施形態>
上述の各実施形態においては、一自由度で継続される軌跡追従制御における車両状態量として、スリップ角β又はヨーレートγの一方が選択された。但し、本発明に係る選択手段の実践的態様は、このような二値的な選択に限定されない。ここで、そのような趣旨に基づいた本発明の第4実施形態について、図7を参照して説明する。ここに、図7は、ヨーレート変化率Δγとヨーレート制御選択率との関係を例示する図である。
<5:第5実施形態>
次に、図8を参照し、本発明の第5実施形態に係るフェールセーフ制御について説明する。ここに、図8は、第5実施形態に係るフェールセーフ制御のフローチャートである。尚、同図において、図4と重複する箇所には同一の符号を付してその説明を適宜省略することとする。
<6:一自由度の軌跡追従制御における車両状態量の制御>
ここで、各実施形態に共通の技術事項として、ステップS202で選択された制御デバイス(状態制御量)に応じた、スリップ角β又はヨーレートγ及び操舵反力トルクTの制御態様(例えば、図4のS205及びS206)について説明する。尚、係る制御態様は、LKA制御のステップS108と同様に、車両運動方程式に基づいた車両運度モデルを利用するものである。以下に、制御デバイスと車両状態量の組み合わせ毎に、状態制御量と車両状態量との関係について説明する。当該組み合わせは、下記(A)乃至)(G)の8種類存在し得る。
この場合、Teps及びδfとT及びγとの関係は下記(28)式を経て下記(29)式として表される。
この場合、Teps及びδfとT及びβとの関係は下記(35)式を経て下記(36)式として表される。
この場合、Teps及びδrとT及びγとの関係は下記(42)式を経て下記(43)式として表される。
この場合、Teps及びδrとT及びβとの関係は下記(49)式を経て下記(50)式として表される。
この場合、Teps及びFfとT及びγとの関係は下記(56)式を経て下記(57)式として表される。
この場合、Teps及びFfとT及びβとの関係は下記(63)式を経て下記(64)式として表される。
この場合、Teps及びFrとT及びγとの関係は下記(70)式を経て下記(71)式として表される。
この場合、Teps及びFrとT及びβとの関係は下記(77)式を経て下記(78)式として表される。
Claims (19)
- 各々がスリップ角又はヨーレートを選択的に制御可能な複数の装置を備える車両の運動を制御する車両の運動制御装置であって、
前記スリップ角の目標値たる目標スリップ角を設定する目標スリップ角設定手段と、
前記ヨーレートの目標値たる目標ヨーレートを設定する目標ヨーレート設定手段と、
前記スリップ角及びヨーレートが其々前記設定された目標スリップ角及び目標ヨーレートとなるように前記複数の装置を制御する旨の挙動制御を実行する挙動制御手段と、
前記車両の旋回状態量を特定する旋回状態量特定手段と、
前記複数の装置のうち一の装置で前記挙動制御を実行する必要がある場合に、前記特定された旋回状態量に基づいて前記スリップ角及びヨーレートのうち優先すべき一方を選択する選択手段と
を具備し、
前記挙動制御手段は、前記一の装置で挙動制御を実行する必要がある場合において、前記選択された一方が前記選択された一方に対応する前記目標値となるように前記一の装置を制御する
ことを特徴とする車両の運動制御装置。 - 前記複数の装置は、各々がスリップ角又はヨーレートを選択的に制御可能な第1装置及び第2装置を含み、
前記車両の運動制御装置は、
前記第1及び第2装置のうち少なくとも一方の装置が機能制限状態にあるか否かを判定する機能制限状態判定手段を更に具備し、
前記選択手段は、前記一の装置で挙動制御を実行する必要がある場合として前記第1又は第2装置が前記機能制限状態にあると判定された場合に前記優先すべき一方を選択し、
前記挙動制御手段は、前記選択された一方が前記選択された一方に対応する目標値となるように、前記一の装置として、前記第1及び第2装置のうち前記機能制限状態にない方の装置を制御する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記第1装置は、前輪舵角を該前輪舵角の変化を促すドライバ操作から独立して変化させることが可能な前輪舵角可変装置であり、
前記第2装置は、後輪舵角を該後輪舵角の変化を促すドライバ操作から独立して変化させることが可能な後輪舵角可変装置である
ことを特徴とする請求の範囲第2項に記載の車両の運動制御装置。 - 前記複数の装置は、前記スリップ角又はヨーレートを選択的に制御可能な前記第1及び第2装置と異なる第3装置を更に含み、
前記挙動制御手段は、前記第1及び第2装置の双方が前記機能制限状態にある場合に、前記選択された一方が前記選択された一方に対応する目標値となるように前記第3装置を制御する
ことを特徴とする請求の範囲第2項に記載の車両の運動制御装置。 - 前記第3装置は、前輪又は後輪の左右制駆動力差を変化させることが可能な制駆動力可変装置である
ことを特徴とする請求の範囲第4項に記載の車両の運動制御装置。 - 前記機能制限状態は、故障している状態及び制御量の選択幅が制限されている状態のうち少なくとも一方を含む
ことを特徴とする請求の範囲第2項に記載の車両の運動制御装置。 - 前記特定手段は、前記旋回状態量として前記車両の旋回度合いを特定する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記選択手段は、前記特定された旋回度合いが基準値以上である場合に前記優先すべき一方として前記ヨーレートを選択し、前記特定された旋回度合いが前記基準値未満である場合に前記優先すべき一方として前記スリップ角を選択する
ことを特徴とする請求の範囲第7項に記載の車両の運動制御装置。 - 前記特定手段は、前記旋回状態量として前記車両の旋回度合いの変化率を特定する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記選択手段は、前記特定された旋回度合いの変化率が基準値以上である場合に前記優先すべき一方として前記ヨーレートを選択し、前記特定された旋回度合いの変化率が前記基準値未満である場合に前記優先すべき一方として前記スリップ角を選択する
ことを特徴とする請求の範囲第9項に記載の車両の運動制御装置。 - 前記特定手段は、前記旋回状態量として前記車両のステア特性を特定する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記選択手段は、前記特定されたステア特性が強アンダーステア状態に該当する場合に前記優先すべき一方として前記ヨーレートを選択し、前記特定されたステア状態が前記強アンダーステア状態に該当しない場合に前記優先すべき一方として前記スリップ角を選択する
ことを特徴とする請求の範囲第11項に記載の車両の運動制御装置。 - 車両挙動の安定の度合いを規定する安定状態量を特定する安定状態量特定手段を更に具備し、
前記選択手段は、前記旋回状態量に基づいた選択に優先して、前記特定された安定状態量に基づいて前記優先すべき一方を選択する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記安定状態量特定手段は、前記安定状態量として前記スリップ角を特定し、
前記選択手段は、前記特定されたスリップ角が基準値以上である場合に前記優先すべき一方として前記スリップ角を選択する
ことを特徴とする請求の範囲第13項に記載の車両の運動制御装置。 - 前記安定状態量特定手段は、前記安定状態量として走行路の摩擦の度合いを特定し、
前記選択手段は、前記特定された摩擦の度合いが基準値未満である場合に前記優先すべき一方として前記スリップ角を選択する
ことを特徴とする請求の範囲第13項又は第14項に記載の車両の運動制御装置。 - 前記目標スリップ角設定手段は、前記車両が目標走行路に追従するように前記目標スリップ角を設定し、
前記目標ヨーレート設定手段は、前記車両が前記目標走行路に追従するように前記目標ヨーレートを設定し、
前記挙動制御手段は、前記挙動制御として、前記スリップ角及びヨーレートが其々前記目標走行路に追従するように設定された目標スリップ角及び目標ヨーレートとなるように前記複数の装置を制御する旨の軌跡追従制御を実行し、
前記車両は、操舵反力を制御可能な操舵反力制御装置を更に備え、
前記車両の運動制御装置は、
前記操舵反力の目標値たる目標操舵反力を設定する目標操舵反力設定手段と、
前記軌跡追従制御と協調して前記操舵反力が前記設定された目標操舵反力となるように前記操舵反力制御装置を制御する旨の協調制御を実行する協調制御実行手段と
を更に具備し、
前記挙動制御手段は、前記一の装置で挙動制御を実行する必要がある場合において、前記選択された一方が前記選択された一方に対応する目標値となるように前記一の装置を制御することにより前記軌跡追従制御を継続し、
前記協調制御実行手段は、前記軌跡追従制御が継続される期間において前記協調制御を継続する
ことを特徴とする請求の範囲第1項に記載の車両の運動制御装置。 - 前記協調制御が継続される期間において前記車両の状態が前記協調制御の終了を許可すべきものとして設定された許可条件に該当するか否かを判定する許可条件判定手段を更に具備し、
前記挙動制御手段は、前記車両の状態が前記許可条件に該当すると判定された場合に前記軌跡追従制御を終了し、
前記協調制御実行手段は、前記車両の状態が前記許可条件に該当すると判定された場合に前記協調制御を終了する
ことを特徴とする請求の範囲第16項に記載の車両の運動制御装置。 - 前記許可条件は、前記車両が停止していることを含む
ことを特徴とする請求の範囲第17項に記載の車両の運動制御装置。 - 前記軌跡追従制御及び前記協調制御が終了した場合に、前記一の装置で挙動制御を実行する必要がある旨を告知する告知手段を更に具備する
ことを特徴とする請求の範囲第16項から第18項のいずれか一項に記載の車両の運動制御装置。
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KR20210081401A (ko) * | 2018-10-22 | 2021-07-01 | 볼보 트럭 코퍼레이션 | 원하는 곡률 경로를 차량이 따르도록 하는 방법 |
KR102637431B1 (ko) | 2018-10-22 | 2024-02-20 | 볼보 트럭 코퍼레이션 | 원하는 곡률 경로를 차량이 따르도록 하는 방법 |
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DE112010006048B4 (de) | 2022-03-31 |
DE112010006048T5 (de) | 2013-09-05 |
CN103237707B (zh) | 2015-05-06 |
US8996254B2 (en) | 2015-03-31 |
CN103237707A (zh) | 2013-08-07 |
JP5494822B2 (ja) | 2014-05-21 |
US20130253770A1 (en) | 2013-09-26 |
JPWO2012073358A1 (ja) | 2014-05-19 |
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