The present invention claims priority under 35 USC 119 based on Japanese patent application No. 2006-247294, filed on Sep. 12, 2006. The entirety of the subject matter of this priority document is incorporated by reference herein.
1. Field of the Invention
The present invention relates to an automatic steering device for a vehicle which minimizes the interference between an automatic steering control operation and a power steering control operation.
2. Description of the Related Art
Japanese Patent Application Laid-open No. 9-193691 (JP '691) discloses a system wherein control of an electric motor for a power steering device is switched between a normal power steering mode for assisting the driver during a steering operation and an automatic steering mode for automatic steering of a vehicle into a predetermined area, such as a garage, or in parallel parking the vehicle into a parking spot. In the automatic steering mode, the automatic steering is performed based on a relationship between a pre-stored moving distance of the vehicle and a turning angle of wheels.
In the system described in JP '691, when the driver applies a steering torque to a steering wheel during the automatic steering control, the steering torque is detected and the automatic steering control is terminated. At that time, interference between the steering operation by the driver and the automatic steering control results in a rather uncomfortable feeling to the driver. Also, when the interference terminates the instant the automatic steering control is terminated, there is yet another uncomfortable feeling sensed by the driver.
The present invention has been achieved in view of the above circumstances, and it is an aspect of the present invention to minimize the interference between the automatic steering control and the power steering control in order to eliminate an uncomfortable feeling sensed by or transmitted to a driver.
To achieve the above aspect, according to a first feature of the present invention, there is provided an automatic steering device for a vehicle, including a steering actuator for steering a wheel of the vehicle. A moving locus setting means stores or calculates a moving locus of the vehicle to a target position. A steering actuator control means calculates a first driving command value to the steering actuator, which is based on the moving locus, and calculates a second driving command value to the steering actuator which is based on a steering force applied by a driver to a steering wheel. The steering actuator control means drives the steering actuator using a control amount, which includes the first driving command value and the second driving command value in a predetermined ratio, and sets the predetermined ratio corresponding to the steering force.
With the first feature, the control amount for driving the steering actuator is calculated using a predetermined ratio of the first driving command value for automatic steering control and the second driving command value for power steering control. The predetermined ratio is set based on the steering force applied by the driver on the steering wheel, that is, an intention of the driver. Therefore, it is possible to solve the problem of the automatic steering control interfering with the power steering control and resulting in an uncomfortable feeling sensed by or transmitted to the driver.
According to a second feature of the present invention, in addition to the first feature, the steering actuator control means sets the predetermined ratio such that a proportion of the first driving command value is reduced as the steering force increases.
With the second feature, when the steering force applied by the driver to the steering wheel increases, the proportion of the first driving command value for the automatic steering control is decreased in the control amounts for driving the steering actuator, and thus, the voluntary steering operation by the driver becomes less hindered by the automatic steering control. Therefore, it is possible to eliminate the uncomfortable feeling sensed by or transmitted to the driver.
According to a third feature of the present invention, in addition to the second feature, the steering actuator control means maintains the proportion of the first driving command value when a direction of the steering force is the same as a direction of the first driving command value.
With the third feature, when the direction of the steering force applied by the driver to the steering wheel is the same as the direction of the first driving command value for the automatic steering control, the first driving command value is maintained rather than reduced. Therefore, it is possible to smoothen the driver's steering operation and eliminate any uncomfortable feeling being sensed by or transmitted to the driver.
According to a fourth feature of the present invention, in addition to the first feature, the steering actuator control means sets the predetermined ratio such that the second driving command value is increased as the steering force increases.
With the fourth feature, when the steering force applied by the driver to the steering wheel increases, the proportion of the second driving command value for the power steering control is increased in the control amount for driving the steering actuator. Thus, priority is given to the voluntary steering operation by the driver over the automatic steering control. Therefore, it is possible to eliminate the uncomfortable feeling being sensed by or transmitted to the driver.
According to a fifth feature of the present invention, in addition to any of the first-to-fourth features, when termination of the automatic steering control is confirmed, the steering actuator control means sets the predetermined ratio as an initial value at the time of confirmation, decreases the proportion of the first driving command value, and increases the proportion of the second driving command value according to an elapsed time from the time termination of the automatic steering control is confirmed.
With the fifth feature, when termination of the automatic steering control is confirmed, the predetermined ratio is established as the initial value at the time of confirmation, the proportion of the first driving command value is decreased, and the proportion of the second driving command value is increased according to the elapsed time from the time termination of the automatic steering control is confirmed. Therefore, it is possible to smoothly shift the automatic steering control to the power steering control and eliminate the driver sensing or receiving an uncomfortable feeling.
A steering actuator control section in the below-described embodiments corresponds to the steering actuator control means of the invention. A memory section in the below-described embodiments corresponds to the moving locus setting means of the invention. An automatic steering control electric current in the below-described embodiments corresponds to the first driving command value of the invention. A power steering control electric current in the below-described embodiments corresponds to the second driving command value of the invention. An actuator driving electric current in the below-described embodiments corresponds to the control amount of the invention. A steering torque in the below-described embodiments corresponds to the steering force of the invention, and front wheels in the below-described embodiments correspond to the wheel of the invention.
The above-mentioned aspect, other aspects, characteristics, and advantages of the present invention will become apparent from preferred embodiments of the present invention which will be described in detail below by reference to the attached drawings.
As shown in
The steering control device 21 includes a control section 22 and a memory section 23. Signals are input to the control section 22 from a steering angle detecting means Sa for detecting a steering angle θ which is a rotation angle of the steering wheel 1; a steering torque detecting means Sb for detecting a steering torque Ts of the steering wheel 1; a wheel rotation angle detecting means Sc for detecting a rotation angle of the wheels Wf, Wf; Wr, Wr; a brake operation amount detecting means Sd for detecting an operation amount of a brake pedal 9; and a shift-range detecting means Se for detecting shift ranges (“D” range, “R” range, “N” range, “P” range and other ranges) selected by a select lever 10.
As shown in
The memory section 23 pre-stores data, in the form of a map, about the above-described parking modes, namely, a relationship between a reference steering angle θref and a moving distance X of the vehicle V (see
The control section 22 controls the operation of the steering actuator 7 as well as operation of an operation stage teaching device 11, which includes a liquid crystal monitor, a speaker, a lamp, a chime, a buzzer and other components, based on signals from the detecting means Sa to Se, the switches Sf and Sg and the data of the parking modes stored in the memory section 23.
Next, operation of the first embodiment of the present invention having the above-described structural configuration and components will be described.
In a normal operation where automatic parking is not performed (where the mode selection switch Sf is not operated), the steering control device 21 is in the power steering mode and functions as a general power steering control device. Specifically, when the steering wheel 1 is operated by a driver in order to turn the vehicle V, the steering torque detecting means Sb detects the steering torque Ts input to the steering wheel 1, and the control section 22 controls the driving of the steering actuator 7 based on the steering torque Ts. As a result, the driving force of the steering actuator 7 turns the right and left front wheels Wf, Wf while assisting the steering operation of the driver.
Next, details of the automatic steering control will be described with reference to the reverse parking/left mode (parking mode where the vehicle V is controlled to travel rearward to a parking position on the left side of the vehicle V). It should be noted that during the period from start to termination of the automatic steering control, the driver does not operate the steering wheel 1.
First, as shown in
It should be noted that door mirrors may be used instead of the marks M provided on the inside of the doors. Also, the marks M or the door mirrors may be aligned with an end of the garage instead of being aligned with the center line of the garage.
In the automatic steering control, when the driver merely lifts his foot off the brake pedal 9 to cause the vehicle V to creep slightly forward, the front wheels Wf, Wf are automatically turned without operation of the steering wheel 1, based on the data of reverse parking/left mode selected by the mode selection switch Sf. Specifically, the front wheels Wf, Wf are automatically turned to the right while the vehicle V travels forward from the start position (1) to the turning-back position (2), and the front wheels Wf, Wf are automatically turned to the left while the vehicle V travels rearward from the turning-back position (2) to the target position (3).
As shown in
The automatic steering control is terminated when the driver turns off the mode selection switch Sf. Also, the control is terminated and returned to the normal power steering control when the driver returns the select lever 10 to the “P” range, when the driver lifts his foot off the brake pedal 9, when the car speed becomes a predetermined value or more, and when the driver applies the steering torque Ts of a predetermined value or more to the steering wheel 1.
The control of the steering actuator 7, when the driver applies the steering torque Ts to the steering wheel 1 during the automatic steering control, will be described below.
As shown in
A first correction coefficient search map MAPSTR for searching a first correction coefficient kSTR with the steering torque Ts as a parameter and a second correction coefficient search map MAPEPS for searching a second correction coefficient kEPS with the steering torque Ts as a parameter are each previously stored in the steering control device 21. The sum of (1) a corrected automatic steering control electric current kSTR·ISTR obtained by multiplying the first correction coefficient kSTR retrieved from the first correction coefficient search map MAPSTR by the automatic steering control electric current ISTR and (2) a corrected power steering control electric current kEPS·IEPS obtained by multiplying the second correction coefficient kEPS retrieved from the second correction coefficient search map MAPEPS by the power steering control electric current IEPS, is outputted as the automatic steering control electric current ISTR.
ICONT=kSTR·ISTR+kEPS·IEPS
A first threshold value TS1 and a second threshold value TS2 are set for an absolute value of the steering torque Ts which is a parameter of the first correction coefficient search map MAPSTR and the second correction coefficient search map MAPEPS. In the first correction coefficient search map MAPSTR, the first correction coefficient kSTR is 100% in a region where the absolute value of the steering torque Ts is less than the first threshold value TS1, linearly decreases from 100% to 0% in a region not less than the first threshold value TS1 and less than the second threshold value TS2, and is fixed at 0% in a region not less than the second threshold value TS2. On the other hand, in the second correction coefficient search map MAPEPS, the first correction coefficient kSTR is 0% in a region where the absolute value of the steering torque Ts is less than the first threshold value TS1, linearly increases from 0% to 100% in a region not less than the first threshold value TS1 and less than the second threshold value TS2, and is fixed at 100% in a region not less than the second threshold value TS2.
Therefore, even when the driver operates the steering wheel 1 during automatic steering control, if the absolute value of the steering torque Ts is less than the first threshold value TS1, the corrected power steering control electric current kEPS·IEPS becomes 0, the corrected automatic steering control electric current kSTR·ISTR becomes the automatic steering control electric current ISTR itself, and genuine automatic steering control is performed rather than power steering control. With this arrangement, even in a case where the driver erroneously touches the steering wheel 1 during the automatic steering control, the automatic steering control is prevented from being affected by the driver's erroneous operation.
Also, when the absolute value of the steering torque Ts applied by the driver to the steering wheel 1 becomes equal to or greater than the second threshold value TS2, the corrected power steering control electric current kEPS·IEPS becomes the power steering control electric current IEPS itself, the corrected automatic steering control electric current kSTR·ISTR becomes 0, and the automatic steering control is forcedly terminated and returned to the power steering control. With this arrangement, even in a case where the driver encounters an obstacle during the automatic steering control and forcefully operates the steering wheel 1, the power steering control easily avoids the obstacle.
Also, when the absolute value of the steering torque Ts applied by the driver to the steering wheel 1 is in a region not less than the first threshold value TS1 and less than the second threshold value TS2, the proportion of the power steering control is increased and the proportion of the automatic steering control is decreased according to an increase of the absolute value of the steering torque Ts. Therefore, it is possible to prevent interference between the power steering control and the automatic steering control, thereby eliminating an uncomfortable feeling being sensed by or transmitted to the driver.
The magnitude of the second threshold value TS2 to forcefully terminate the automatic steering control is set to be smaller than the magnitude of the steering torque Ts applied by the driver to the steering wheel 1 during the normal power steering control. With this arrangement, when the driver operates the steering wheel 1 during automatic steering control so that the automatic steering control is forcefully terminated and shifted to the power steering control, the power steering control enables the steering actuator 7 to generate an assist torque equal to or greater than the second threshold value TS2. Therefore, it is possible to prevent a situation where the steering wheel 1 suddenly becomes heavy when switching the control, thereby eliminating an uncomfortable feeling being sensed by or transmitted to the driver.
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As described above, by changing the setting of the first correction coefficient search map MAPSTR and the second correction coefficient search map MAPEPS for searching the first correction coefficient kSTR and the second correction coefficient kEPS, the ratio between the automatic steering control and the power steering control is arbitrarily changed even if the driver applies the steering torque Ts to the steering wheel 1 during the automatic steering control, thereby eliminating an uncomfortable feeling being sensed by or transmitted to the driver while maintaining the function of the automatic steering control.
Next, based on
When the automatic steering control is terminated and switched to the power steering control, if the actuator driving electric current ICONT is switched from the automatic steering control electric current ISTR to the power steering control electric current IEPS, the steering wheel 1 can suddenly be stopped. Also, if the driver applies the steering torque Ts to the steering wheel 1 to terminate the automatic steering control, the steering torque Ts, generated by the steering actuator 7, is rapidly changed which causes an uncomfortable feeling being sensed by or transmitted to the driver.
Thus, a first time coefficient TSTR (0%≦ηSTR≦100%) and a second time coefficient ηEPS (0%≦ηEPS≦100%), which are functions of time t, are established, and the actuator driving electric current ICONT is corrected using the first time coefficient ηSTR and the second time coefficient ηEPS during the transition period from the confirmation of termination of the automatic steering control to the start of the power steering control.
ICONT=ηSTR·ISTR+ηEPSIEPS
where the first time coefficient ηSTR is:
when t=t0: ηSTR=kSTRE
when t0≦t≦t1s: ηSTR=kSTRE·α(t−t0)
when t1s≦t: ηSTR=0%
where the second time coefficient ηEPS is:
when t=t0: ηEPS=kEPSE
when t0<t<t1e: ηEPS=kEPSE·α(t−t0)
when t1e≦t: ηEPS=0%.
Also, t0 is a time when termination of the automatic steering control is confirmed, t1s is a time when the first time coefficient ηSTR reaches 0%, and t1e is a time when the second time coefficient ηEPS reaches 100%. Moreover, kSTRE is the first correction coefficient kSTR at the time t0, kEPSE is the second correction coefficient kEPS at the time t0, and α is a change rate of the first time coefficient ηSTR and the second time coefficient ηEPS with respect to the time t.
Time charts in
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As described above, the first correction coefficient kSTR is gradually decreased and the second correction coefficient kEPS is gradually increased in the switching transition period from confirming termination of the automatic steering control to starting the power steering control. Therefore, it is possible to prevent a rapid change of the steering torque Ts generated by the steering actuator 7, thereby eliminating an uncomfortable feeling being sensed by the driver.
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Next, a second embodiment of the present invention will be described with reference to
In the first embodiment, the corrected automatic steering control electric current kSTR·ISTR is obtained by multiplying the first correction coefficient kSTR by the automatic steering control electric current ISTR; the corrected power steering control electric current kEPS·IEPS is obtained by multiplying the second correction coefficient kEPS by the power steering control electric current IEPS; and the automatic steering control electric current ISTR is obtained by adding the corrected automatic steering control electric current kSTR·ISTR and the corrected power steering control electric current kEPS·IEPS.
On the other hand, in the second embodiment, if the direction of the steering torque Ts is different from the direction of the automatic steering control electric current ISTR, that is, if the driver operates the steering wheel 1 in a direction against the automatic steering control, the same control as in the first embodiment is performed. However, if the direction of the steering torque Ts is the same as the direction of the automatic steering control electric current ISTR, that is, if the driver operates the steering wheel 1 in a direction that is not against the automatic steering control, the automatic steering control electric current ISTR, before being multiplied by the first correction coefficient kSTR, is added to the corrected power steering control electric current kEPS·IEPS to obtain the automatic steering control electric current ISTR.
As can be observed from the first correction coefficient search map MAPSTR in
Then, in the second embodiment, the automatic steering control electric current ISTR, before being multiplied with the first correction coefficient kSTR, is maintained as it is, thereby preventing the actuator driving current ICONT from decreasing in order to eliminate an uncomfortable feeling being sensed by or transmitted to the driver.
The embodiments of the present invention have been described above, but various changes in design can be made to the present invention without departing from the subject matter thereof.
For example, in the embodiments, the moving locus of the vehicle V to the target position (3) is stored beforehand in the memory section 23, but the moving locus can be calculated from the current position and the target position (3) of the vehicle V.
Also, in the embodiments, the first correction coefficient kSTR and the second correction coefficient kEPS are map-searched with the steering torque Ts as a parameter, but they can be calculated as functions of the steering torque Ts instead of performing a map-search.
Number | Date | Country | Kind |
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2006-247294 | Sep 2006 | JP | national |
Number | Name | Date | Kind |
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7431117 | Ito | Oct 2008 | B2 |
20060037806 | Kasahara et al. | Feb 2006 | A1 |
Number | Date | Country |
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9-193691 | Jul 1997 | JP |
2002-002519 | Jan 2002 | JP |
2004-256076 | Sep 2004 | JP |
2005-162015 | Jun 2005 | JP |
Number | Date | Country | |
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20080091320 A1 | Apr 2008 | US |