The present invention relates to an electric power steering apparatus for applying steering assist power via a motor.
In an electric power steering apparatus comprising a motor for generating steering assist power, the steering assist power is varied in accordance with driving conditions such as the steering torque and vehicle speed. Further, the output of the motor for providing steering assist power is corrected in accordance with the rotation angular velocity or rotation angular acceleration of the motor or steering wheel, steering torque, change velocity of the steering torque, steering angle change velocity of vehicle wheels, and so on, so that the influence of inertia of the motor is compensated by improvement of the steering response, and the influence of disturbance is decreased by providing the steering system with viscosity (c.f., Japanese Patent No. 2773325; Japanese Patent No. 2767637; Japanese Patent No. 2694213; Japanese Patent Laid-Open Publication No. 1993-238409; Japanese Patent No. 3050036; Japanese Patent No. 2782254; Japanese Patent No. 2546673; Japanese Examined Patent Publication No. 1995-84178; Japanese Examined Patent Publication No. 1995-75986; Japanese Patent Laid-Open Publication No. 2002-302057; Japanese Patent Laid-Open Publication No. 2002-29435; Japanese Patent Laid-Open Publication No. 2002-24929; Japanese Patent Laid-Open Publication No. 2001-106108; and Japanese Patent Laid-Open Publication No. 1994-99836).
However, according to the conventional technology, it was not possible to reduce the influence of disturbance without deteriorating the steering response. For instance, in a rack and pinion type electric power steering apparatus which transmits the rotation of the steering wheel to the pinion via a torsion bar, when correcting the motor output according to the rotation angular velocity of the motor for generating steering assist power, it is possible to obtain the board diagrams representing the frequency response characteristic shown by
Here, it is assumed that the input torque Ti to the steering system via the motor is determined with the following formula which subtracts the correction torque T′ proportional to the rotation angular velocity of the motor from the basic assist torque To proportional to the steering torque.
Ti=To−T′
To=Ka·Ks (θh−θp)
T′=Kdo·dθm/dt
θh is the steering angle of the steering wheel, θm is the rotation angle of the motor, Ka is a basic assist control gain, Kdo is a control gain of the rotation angular velocity dθm/dt upon correcting the motor output in accordance with the rotation angular velocity dθm/dt of the motor, and Ks is a spring constant of the torsion bar.
In the relationship of the steering frequency and the amplitude ratio of the steering torque relative to the steering angle shown in
ω1=(K/Jp)1/2 (A)
ζ1=(Cp+Kdo)/{2·(Jp·α1/α2)1/2} (B)
The frequency ω2 and damping ratio ζ2 in the relationship of the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque shown in
ω2=[{Ks·(1+Ka)+K}/Jp]1/2 (C)
ζ2=(Cp+Kdo)/{2·(Jp·Ks/α1)1/2} (D)
α1 is a parameter of the weight of steering when the frequency is zero, and α2 is a transmission ratio of disturbance when the frequency is zero, and are represented by the following formulas.
α1=Ks·K/{Ks·(1+Ka)+K}
α2=1/{(1+Ka)+K/Ks}
K is an elastic coefficient of the steering system, Jp is an inertia of the pinion axis conversion in the steering system, and Cp is a pinion axis conversion viscosity coefficient in the steering system lower than the torsion bar.
In
Meanwhile, in
Further, according to the conventional technology, it was not possible to simultaneously improve the steering response and reduce the influence of disturbance in a sufficient manner. For instance, in a rack and pinion type electric power steering apparatus which transmits the rotation of the steering wheel to the pinion via a torsion bar, when the output of the motor for generating steering assist power is corrected according to the rotation angular acceleration of the motor, it is possible to obtain the board diagrams representing the frequency response characteristic shown in
Here, it is assumed that the input torque Ti to the steering system via the motor is determined with the following formula which adds the correction torque T′ proportional to the rotation angular acceleration of the motor to the basic assist torque To proportional to the steering torque.
Ti=To+T′
To=Ka·Ks(θh−θp)
T′=Km·d2θm/dt2
θh is the steering angle of the steering wheel, θm is the rotation angle of the motor, Ka is a basic assist control gain, Km is a control gain of the rotation angular acceleration d2θm/dt2 upon correcting the motor output in accordance with the rotation angular acceleration d2θm/dt2 of the motor, and Ks is a spring constant of the torsion bar.
In the relationship of the steering frequency and the amplitude ratio of the steering torque relative to the steering angle shown in
ω1={K/(Jp−Km)}1/2 (E)
ζ1=Cp/[2·{(Jp−Km)·α1/α2}1/2] (F)
The frequency ω2 and damping ratio ζ2 in the relationship of the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque shown in
ω2=[{Ks·(1+Ka)+K}(Jp−Km)]1/2 (G)
ζ2=Cp/[2·{(Jp−Km)·Ks/α1}1/2] (H)
α1 is a parameter of the weight of steering when the frequency is zero, and α2 is a transmission ratio of disturbance when the frequency is zero, and are represented by the following formulas.
α1=Ks·K/{Ks·(1+Ka)+K}
α2=1/{(1+Ka)+K/Ks}
K is an elastic coefficient of the steering system, Jp is an inertia of the pinion axis conversion in the steering system, and Cp is a pinion axis conversion viscosity coefficient in the steering system lower than the torsion bar.
In
Meanwhile, in
An object of the present invention is to provide an electric power steering apparatus capable of overcoming the foregoing problem.
The present invention is applied to an electric power steering apparatus comprising a motor for generating steering assist power; a means for determining the steering torque required to operate a steering wheel; and a means for controlling the motor so as to generate the steering assist power according to the determined steering torque.
In one aspect of the present invention, the electric power steering apparatus includes: a means for determining a rotation angular velocity correspondence value corresponding to the rotation angular velocity of the steering wheel; a means for determining a change velocity correspondence value corresponding to the change velocity of the steering torque; a means for storing a first relation set between the rotation angular velocity correspondence value and a first motor output correction value correlating with the rotation angular velocity correspondence value; a means for storing a second relation set between the change velocity correspondence value and a second motor output correction value directly correlating with the change velocity correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined rotation angular velocity correspondence value and the second motor output correction value corresponding to the determined change velocity correspondence value; wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio is within a setting range as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the amplitude ratio becomes smaller at the resonance frequency as a result of correction of the output of the motor.
As a result, since the amplitude ratio does not become too large or too small at least within the steering frequency range when a person operates the steering wheel, the feel of steering does not become inferior. Further, since the amplitude ratio of the steering torque relative to the disturbance torque becomes smaller at the resonance frequency, the influence of disturbance to the steering can be suppressed.
In another aspect of the present invention, the electric power steering apparatus includes: a means for determining a rotation angular velocity correspondence value corresponding to the rotation angular velocity of the motor; a means for determining a change velocity correspondence value corresponding to the change velocity of the steering torque; a means for storing a first relation set between the rotation angular velocity correspondence value and a first motor output correction value correlating with the rotation angular velocity correspondence value; a means for storing a second relation set between the change velocity correspondence value and a second motor output correction value directly correlating with the change velocity correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined rotation angular velocity correspondence value and the second motor output correction value corresponding to the determined change velocity correspondence value; a wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio is within a setting range as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the amplitude ratio becomes smaller at a resonance frequency as a result of correction of the output of the motor.
As a result, since the amplitude ratio does not become too large or too small at least within the steering frequency range when a person operates the steering wheel, the feel of steering does not become inferior. Further, since the amplitude ratio of the steering torque relative to the disturbance torque becomes smaller at the resonance frequency, the influence of disturbance to the steering can be suppressed.
In another aspect of the present invention, the electric power steering apparatus includes: a means for determining a first rotation angular velocity correspondence value corresponding to the rotation angular velocity of the steering wheel; a means for determining a second rotation angular velocity correspondence value corresponding to the rotation angular velocity of the motor; a means for storing a first relation set between the first rotation angular velocity correspondence value and a first motor output correction value correlating with the first rotation angular velocity correspondence value; a means for storing a second relation set between the second rotation angular velocity correspondence value and a second motor output correction value inversely correlating with the second rotation angular velocity correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined first rotation angular velocity correspondence value and the second motor output correction value corresponding to the determined second rotation angular velocity correspondence value; wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio is within a setting range as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the amplitude ratio becomes smaller at the resonance frequency as a result of correction of the output of the motor.
As a result, since the amplitude ratio does not become too large or too small at least within the steering frequency range when a person operates the steering wheel, the feel of steering does not become inferior. Further, since the amplitude ratio of the steering torque relative to the disturbance torque becomes smaller at the resonance frequency, the influence of disturbance to the steering can be suppressed.
As described above, by correcting the motor output in accordance with the first motor output correction value correlating with the rotation angular velocity of the steering wheel, in the frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the amplitude ratio can be arbitrarily set at least within the steering frequency range when a person operates the steering wheel. Thus, the influence of disturbance can be decreased without deteriorating the feel of steering, by correcting the output of the motor in accordance with the sum of the first motor output correction value and the second motor output correction value corresponding to the change velocity of the physical quantity influencing the steering torque. Accordingly, in the present invention, the electric power steering apparatus includes: a means for determining a rotation angular velocity correspondence value corresponding to the rotation angular velocity of the steering wheel; a means for determining a change velocity correspondence value corresponding to the change velocity of the physical quantity influencing the steering torque; a means for storing a first relation set between the rotation angular velocity correspondence value and a first motor output correction value correlating with the rotation angular velocity correspondence value; a means for storing a second relation set between the change velocity correspondence value and a second motor output correction value correlating with the change velocity correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined rotation angular velocity correspondence value and the second motor output correction value corresponding to the determined change velocity correspondence value; wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio is within a setting range as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the amplitude ratio becomes smaller at the resonance frequency as a result of correction of the output of the motor.
Thus, according to the electric power steering apparatus of the present invention, the influence of disturbance can be reduced without deteriorating the feel of steering.
In another aspect of the present invention, the electric power steering apparatus includes: a means for determining a rotation angular acceleration correspondence value corresponding to the rotation angular acceleration of the steering wheel; a means for determining a change acceleration correspondence value corresponding to the change acceleration of the steering torque; a means for storing a first relation set between the rotation angular acceleration correspondence value and a first motor output correction value directly correlating with the rotation angular acceleration correspondence value; a means for storing a second relation set between the change acceleration correspondence value and a second motor output correction value directly correlating with the change acceleration correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined rotation angular acceleration correspondence value and the second motor output correction value corresponding to the determined change acceleration correspondence value; wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio becomes smaller under the same frequency as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the resonance frequency at which the amplitude ratio reaches the peak value becomes smaller as a result of correction of the output of the motor.
With the result that the amplitude ratio of the steering torque relative to the steering angle of the steering wheel becomes smaller at least within the steering frequency range when a person operates the steering wheel, the steering response can be improved. Further, since the resonance frequency of the steering system in which the amplitude ratio of the steering torque relative to the disturbance torque reaches a peak value becomes smaller, the input frequency of the disturbance torque corresponding to such resonance frequency becomes smaller, the frequency range of disturbance in which the disturbance has an influence becomes narrow, and the influence of disturbance to the steering can be suppressed thereby.
In another aspect of the present invention, the electric power steering apparatus includes: a means for determining a rotation angular acceleration correspondence value corresponding to the rotation angular acceleration of the motor; a means for determining a change acceleration correspondence value corresponding to the change acceleration of the steering torque; a means for storing a first relation set between the rotation angular acceleration correspondence value and a first motor output correction value directly correlating with the rotation angular acceleration correspondence value; a means for storing a second relation set between the change acceleration correspondence value and a second motor output correction value directly correlating with the change acceleration correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined rotation angular acceleration correspondence value and the second motor output correction value corresponding to the determined change acceleration correspondence value; wherein, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio becomes smaller under the same frequency as a result of correction of the output of the motor, at least within the steering frequency range when a person operates the steering wheel; and in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the resonance frequency at which the amplitude ratio reaches the peak value becomes smaller as a result of correction of the output of the motor.
With the result that the amplitude ratio of the steering torque relative to the steering angle of the steering wheel becomes smaller at least within the steering frequency range when a person operates the steering wheel, the steering response can be improved. Further, since the resonance frequency of the steering system in which the amplitude ratio of the steering torque relative to the disturbance torque reaches a peak value becomes smaller, the input frequency of the disturbance torque corresponding to such resonance frequency becomes smaller, the frequency range of disturbance in which the disturbance has an influence becomes narrow, and the influence of disturbance to the steering can be suppressed thereby.
In another aspect of the present invention, the electric power steering apparatus includes: a means for determining a first rotation angular acceleration correspondence value corresponding to the rotation angular acceleration of the steering wheel; a means for determining a second rotation angular acceleration correspondence value corresponding to the rotation angular acceleration of the motor; a means for storing a first relation set between the first rotation angular acceleration correspondence value and a first motor output correction value directly correlating with the first rotation angular acceleration correspondence value; a means for storing a second relation set between the second rotation angular acceleration correspondence value and a second motor output correction value inversely correlating with the second rotation angular acceleration correspondence value; and a means for correcting the output of the motor in accordance with the sum of the first motor output correction value corresponding to the determined first rotation angular acceleration correspondence value and the second motor output correction value corresponding to the determined second rotation angular acceleration correspondence value; wherein, as a result of correction of the output of the motor in accordance with the first motor output correction value, in a frequency response characteristic represented by the steering frequency of the steering wheel and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel, the first relation is set such that the amplitude ratio becomes smaller under the same frequency, at least within the steering frequency range when a person operates the steering wheel; and as a result of correction of the output of the motor in accordance with the second motor output correction value, in a frequency response characteristic represented by the frequency of the disturbance torque input from the road surface to the steering system via vehicle wheels and the amplitude ratio of the steering torque relative to the disturbance torque, the second relation is set such that the resonance frequency at which the amplitude ratio reaches the peak value becomes smaller.
With the result that the amplitude ratio of the steering torque relative to the steering angle of the steering wheel becomes smaller at least within the steering frequency range when a person operates the steering wheel, the steering response can be improved. Further, since the resonance frequency of the steering system in which the amplitude ratio of the steering torque relative to the disturbance torque reaches a peak value becomes smaller, the input frequency of the disturbance torque corresponding to such resonance frequency becomes smaller, the frequency range of disturbance in which the disturbance has an influence becomes narrow, and the influence of disturbance to the steering can be suppressed thereby.
Thus, according to the electric power steering apparatus of the present invention, the influence of disturbance can be reduced simultaneously while improving the steering response.
An electric power steering apparatus 1 for vehicles according to the first embodiment shown in
A motor 10 for generating steering assist power which acts on the path for transmitting the rotation of the steering wheel 2 to the vehicle wheels 3 is provided. In the present embodiment, the steering assist power is applied by transmitting the rotation of the output shaft of the motor 10 to the steering shaft 4 via a reduction gear mechanism 11.
The motor 10 is connected to a controller 20 constituted of a computer via a drive circuit 21. A torque sensor 22 for determining the steering torque T required to operate the steering wheel 2, a steering angle sensor 23 for determining the steering angle θh corresponding to the rotation angle of the steering wheel 2, a vehicle speed sensor 24 for determining the vehicle speed V, and a current sensor 26 for determining the drive current i of the motor 10 are connected to the controller 20. Incidentally, the steering shaft of the present embodiment is comprised of two parts, one of which is located at the side of the steering wheel 2 and the other is located at the side of the pinion 5, and the two parts are connected with a torsion bar 29. The torque sensor 22 determines the steering torque T obtained by multiplying the spring constant Ks of the torsion bar 29 to the torsion angle (θh−θp) of the torsion bar 29, which is the difference between the steering angle θh and the rotation angle θp of the pinion 5.
The controller 20 controls the motor 10 such that it generates steering assist power in accordance with the determined steering torque T, varies the steering assist power in accordance with the determined vehicle speed V, and further corrects the steering assist power in accordance with the rotation angular velocity of the steering wheel 2 and the change velocity of the steering torque T.
As shown in
The relation set between the absolute value of the steering torque T and the first torque gain Gta is stored as a table or an arithmetic expression for example, and the first torque gain Gta corresponding to the determined steering torque T is calculated in a calculation part 32. Regarding the relation between the absolute value of the steering torque T and the first torque gain Gta, as shown in the calculation part 32 of
Further, the relation set between the vehicle speed V and the first vehicle speed gain Gva is stored as a table or an arithmetic expression for example, and the first vehicle speed gain Gva corresponding to the determined vehicle speed V is calculated in a calculation part 33. Regarding the relation between the vehicle speed V and the first vehicle speed gain Gva, as shown in the calculation part 33 of
The first correction current i1 is determined by multiplying the first torque gain Gta and the first vehicle speed gain Gva to the first correction reference current ia in the multiplication parts 34, 35. As a result, the relation set as shown in the calculation parts 31, 32, 33 of
As shown in
The relation set between the absolute value of the steering torque T and the second torque gain Gtb is stored as a table or an arithmetic expression for example, and the second torque gain Gtb corresponding to the determined steering torque T is calculated in a calculation part 37. Regarding the relation between the absolute value of the steering torque T and the second torque gain Gtb, as shown in the calculation part 37 of
Further, the relation set between the vehicle speed V and the second vehicle speed gain Gvb is stored as a table or an arithmetic expression for example, and the second vehicle speed gain Gvb corresponding to the determined vehicle speed V is calculated in a calculation part 38. Regarding the relation between the vehicle speed V and the second vehicle speed gain Gvb, as shown in the calculation part 38 of
The second correction current i2 is determined by multiplying the second torque gain Gtb and the second vehicle speed gain Gvb to the second correction reference current ib in the multiplication parts 39, 40. As a result, the relation set as shown in the calculation parts 36, 37, 38 of
As shown in
The relation between the vehicle speed V and the basic vehicle speed gain Gv is stored as a table or an arithmetic expression for example, and the basic vehicle speed gain Gv corresponding to the determined vehicle speed V is calculated in a calculation part 42. Regarding the relation between the vehicle speed V and the basic vehicle speed gain Gv, as shown in the calculation part 42 of
The sum of the first correction current i1 and the second correction current i2 and the basic assist current io is calculated in an addition part 43, and the target drive current i* is determined by multiplying the basic vehicle speed gain Gv to such sum in a multiplication part 44. As a result, the output of the motor 10 corresponding to the basic assist current io according to the steering torque is corrected in accordance with the sum of the first correction current i1 and the second correction current i2.
The flowchart of
According to the first embodiment described above, the board diagrams representing the frequency response characteristic shown by
For example, it is assumed that the input torque Ti to the steering system via the motor 10 is determined with the following formula which adds the basic assist torque To proportional to the steering torque, the first correction torque inversely proportional to the rotation angular velocity of the steering wheel 2, and the second correction torque Tb proportional to the change velocity of the steering torque.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=Kdi·dθh/dt
Tb=Kd·d{Ks(θh−θp)}/dt
Ka is a basic assist control gain, Kdi is a control gain of the steering angular velocity (steering angle differentiation), and Kd is a torque differentiation control gain.
In the frequency response characteristic shown in
ω1=(K/Jp)1/2 (1)
ζ1=(Cp+Kdi)/{2·(Jp·α1/α2)1/2} (2)
In the frequency response characteristic shown in
ω2=[{Ks·(1+Ka)+K}/Jp]1/2 (3)
ζ2=(Cp+Kd)/{2·(Jp·Ks/α1)1/2} (4)
α1 is a parameter of the weight of steering when the frequency is zero, and α2 is a transmission ratio of disturbance when the frequency is zero, and are represented by the following formulas.
α1=Ks·K/{Ks·(1+Ka)+K}
α2=1/{(1+Ka)+K/Ks}
K is an elastic coefficient of the steering system, Jp is an inertia of the pinion axis conversion in the steering system, and Cp is a pinion axis conversion viscosity coefficient in the steering system lower than the torsion bar 29.
In
In
As shown in
The relation set between the absolute value of the steering torque T and the first torque gain Gtc is stored as a table or an arithmetic expression for example, and the first torque gain Gtc corresponding to the determined steering torque T is calculated in a calculation part 32′. Regarding the relation between the absolute value of the steering torque T and the first torque gain Gtc, as shown in the calculation part 32′ of
Further, the relation set between the vehicle speed V and the first vehicle speed gain Gvc is stored as a table or an arithmetic expression for example, and the first vehicle speed gain Gvc corresponding to the determined vehicle speed V is calculated in a calculation part 33′. Regarding the relation between the vehicle speed V and the first vehicle speed gain Gvc, as shown in the calculation part 33′ of
The first correction current i1 is determined by multiplying the first torque gain Gtc and the first vehicle speed gain Gvc to the first correction reference current ic in the multiplication parts 34, 35. As a result, the relation set as shown in the calculation parts 31′, 32′, 33′ of
The second correction current i2 directly correlating with the change velocity dT/dt is determined as with the first embodiment.
The flowchart of
According to the second embodiment described above, board diagrams similar to the board diagrams representing the frequency response characteristic shown in
For example, the input torque Ti is determined with the following formula.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=−Kdo·dθm/dt
Tb=Kd·d{Ks(θh−θp)}/dt
Kdo is a control gain of the motor rotation angular velocity (motor rotation angle differentiation).
In the frequency response characteristic represented by the steering frequency and the amplitude ratio of the steering torque T relative to the steering angle θh, the frequency ω1 and damping ratio ζ1 are determined with the following formulas.
ω1=(K/Jp)1/2 (5)
ζ1=(Cp+Kdo)/{2·(Jp·α1/α2)1/2} (6)
In the frequency response characteristic represented by the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque, the frequency ω2 and damping ratio ζ2 are determined with the following formulas.
ω2=[{Ks·(1+Ka)+K}/Jp]1/2 (7)
ζ2=(Cp+Kdo+Kd)/{2·(Jp·Ks/α1)1/2} (8)
Since the first correction current i1 is inversely correlating with the rotation angular velocity dθm/dt of the motor 10 and the gain of such rotation angular velocity dθm/dt is Kdo, the damping ratio ζ1 increases pursuant to the above-mentioned formula (6) when the motor output is corrected. Nevertheless, by setting the gain Kdo to a value that is not so large, as shown with the dotted line after correction relative to the solid line before correction in
Since the second correction current i2 is directly correlating with the change velocity dT/dt of the steering torque T and the gain of such change velocity dT/dt is Kd, the damping ratio ζ2 increases pursuant to the above-mentioned formula (8) when the motor output is corrected. In other words, the dotted line after correction shifts relative to the solid line before correction in
As shown in
The relation set between the absolute value of the steering torque T and the first torque gain Gtd is stored as a table or an arithmetic expression for example, and the first torque gain Gtd corresponding to the determined steering torque T is calculated in a calculation part 32″. Regarding the relation between the absolute value of the steering torque T and the first torque gain Gtd, as shown in the calculation part 32″ of
Further, the relation set between the vehicle speed V and the first vehicle speed gain Gvd is stored as a table or an arithmetic expression for example, and the first vehicle speed gain Gvd corresponding to the determined vehicle speed V is calculated in a calculation part 33″. Regarding the relation between the vehicle speed V and the first vehicle speed gain Gvd, as shown in the calculation part 33″ of
The first correction current i1 is determined by multiplying the first torque gain Gtd and the first vehicle speed gain Gvd to the first correction reference current id in the multiplication parts 34, 35. As a result, the relation set as shown in the calculation parts 31″, 32″, 33″ of
As shown in
The relation set between the steering torque T and the second torque gain Gte is stored as a table or an arithmetic expression for example, and the second torque gain Gte corresponding to the determined steering torque T is calculated in a calculation part 37′. Regarding the relation between the absolute value of the steering torque T and the second torque gain Gte, as shown in the calculation part 37′ of
Further, the relation set between the vehicle speed V and the second vehicle speed gain Gve is stored as a table or an arithmetic expression for example, and the second vehicle speed gain Gve corresponding to the determined vehicle speed V is calculated in a calculation part 38′. Regarding the relation between the vehicle speed V and the second vehicle speed gain Gve, as shown in the calculation part 38′ of
The second correction current i2 is determined by multiplying the second torque gain Gte and the second vehicle speed gain Gve to the second correction reference current ie in the multiplication parts 39, 40. As a result, the relation set as shown in the calculation parts 36′, 37′, 38′ of
The flowchart of
According to the third embodiment described above, board diagrams similar to the board diagrams representing the frequency response characteristic shown in
For example, the input torque Ti is determined with the following formulas.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=Kdi·dθh/dt
Th=−Kdo·dθm/dt
In the frequency response characteristic represented by the steering frequency and the amplitude ratio of the steering torque T relative to the steering angle θh, the frequency ω1 and damping ratio ζ1 are determined with the following formulas.
ω1=(K/Jp)1/2 (9)
ζ1=(Cp+Kdi+Kdo)/{2·(Jp·α1/α2)1/2} (10)
In the frequency response characteristic represented by the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque, the frequency ω2 and damping ratio ζ2 are determined with the following formulas.
ω2=[{Ks·(1+Ka)+K}/Jp]1/2 (11)
ζ2=(Cp+Kdo)/{2·(Jp·Ks/α1)1/2} (12)
Since the first correction current i1 is directly correlating with the rotation angular velocity dθh/dt of the steering wheel 2 and the gain of such rotation angular velocity dθh/dt is Kdi, when the motor output is corrected, the damping ratio ζ1 increases pursuant to the above mentioned formula (10) when focusing only on the gain Kdi. In addition, the foregoing formula (10) includes the gain Kdo inversely correlating with the rotation angular velocity dθm/dt of the motor 10, and when the motor output is corrected, the damping ratio ζ1 increases when focusing only on the gain Kdo. Nevertheless, the gain Kdi does not influence the damping ratio ζ2 based on the formula (12). Thus, by setting the gain Kdi to an appropriate value, as shown with the dotted line after correction relative to the solid line before correction in
Since the second correction current i2 is inversely correlating with the rotation angular velocity dθm/dt of the motor 10 and the gain of such rotation angular velocity dθm/dt is Kdo, when the motor output is corrected, the damping ratio ζ2 increases pursuant to the above-mentioned formula (12). In other words, the dotted line after correction shifts relative to the solid line before correction in
As a result of correcting the output of the motor 10 in accordance with the first correction current i1 correlating with the rotation angular velocity dθh/dt of the steering wheel 2 as shown in the first to third embodiments described above, in the frequency response characteristic represented by the steering frequency of the steering wheel 2 and the amplitude ratio of the steering torque relative to the steering angle of the steering wheel 2, the amplitude can be arbitrarily set at least within the steering frequency range when a person operates the steering wheel 2. As a result, by correcting the output of the motor 10 in accordance with the sum of the first correction current i1 and the second correction current i2 corresponding to the change velocity of the physical quantity influencing the steering torque, the influence of disturbance can be reduced without deteriorating the feel of steering.
The electric power steering apparatus 1 for vehicles according to the fourth embodiment shown in
A motor 10 for generating steering assist power which acts on the path for transmitting the rotation of the steering wheel 2 to the vehicle wheels 3 is provided. In the present embodiment, the steering assist power is applied by transmitting the rotation of the output shaft of the motor 10 to the steering shaft 4 via a reduction gear mechanism 11.
The motor 10 is connected to a controller 20 constituted of a computer via a drive circuit 21. A torque sensor 22 for determining the steering torque T required to operate the steering wheel 2, a steering angle sensor 23 for determining the steering angle θh corresponding to the rotation angle of the steering wheel 2, a vehicle speed sensor 24 for determining the vehicle speed V, and a current sensor 26 for determining the drive current i of the motor 10 are connected to the controller 20. Incidentally, the steering shaft of the present embodiment is comprised of two parts, one of which is located at the side of the steering wheel 2 and the other is located at the side of the pinion 5, and the two parts are connected with a torsion bar 29. The torque sensor 22 determines the steering torque T obtained by multiplying the spring constant Ks of the torsion bar 29 to the torsion angle (θh−θp) of the torsion bar 29, which is the difference between the steering angle θh and the rotation angle θp of the pinion 5.
The controller 20 controls the motor 10 such that it generates steering assist power in accordance with the determined steering torque T, varies the steering assist power in accordance with the determined vehicle speed V, and further corrects the steering assist power in accordance with the rotation angular velocity of the steering wheel 2 and the change velocity of the steering torque T.
As shown in
The relation set between the absolute value of the steering torque T and the first torque gain Gta is stored as a table or an arithmetic expression for example, and the first torque gain Gta corresponding to the determined steering torque T is calculated in a calculation part 32. Regarding the relation between the absolute value of the steering torque T and the first torque gain Gta, as shown in the calculation part 32 of
Further, the relation set between the vehicle speed V and the first vehicle speed gain Gva is stored as a table or an arithmetic expression for example, and the first vehicle speed gain Gva corresponding to the determined vehicle speed V is calculated in a calculation part 33. Regarding the relation between the vehicle speed V and the first vehicle speed gain Gva, as shown in the calculation part 33 of
The first correction current i1 is determined by multiplying the first torque gain Gta and the first vehicle speed gain Gva to the first correction reference current ia in the multiplication parts 34, 35. As a result, the relation set as shown in the calculation parts 31, 32, 33 of
As shown in
The relation set between the absolute value of the steering torque T and the second torque gain Gtb is stored as a table or an arithmetic expression for example, and the second torque gain Gtb corresponding to the determined steering torque T is calculated in a calculation part 37. Regarding the relation between the absolute value of the steering torque T and the second torque gain Gtb, as shown in the calculation part 37 of
Further, the relation set between the vehicle speed V and the second vehicle speed gain Gvb is stored as a table or an arithmetic expression for example, and the second vehicle speed gain Gvb corresponding to the determined vehicle speed V is calculated in a calculation part 38. Regarding the relation between the vehicle speed V and the second vehicle speed gain Gvb, as shown in the calculation part 38 of
The second correction current i2 is determined by multiplying the second torque gain Gtb and the second vehicle speed gain Gvb to the second correction reference current ib in the multiplication parts 39, 40. As a result, the relation set as shown in the calculation parts 36, 37, 38 of
As shown in
The relation between the vehicle speed V and the basic vehicle speed gain Gv is stored as a table or an arithmetic expression for example, and the basic vehicle speed gain Gv corresponding to the determined vehicle speed V is calculated in a calculation part 42. Regarding the relation between the vehicle speed V and the basic vehicle speed gain Gv, as shown in the calculation part 42 of
The sum of the first correction current i1 and the second correction current i2 and the basic assist current io is calculated in an addition part 43, and the target drive current i* is determined by multiplying the basic vehicle speed gain Gv to such sum in a multiplication part 44. As a result, the output of the motor 10 corresponding to the basic assist current io according to the steering torque is corrected in accordance with the sum of the first correction current i1 and the second correction current i2.
The flowchart of
According to the fourth embodiment described above, the board diagrams representing the frequency response characteristic shown in
For example, it is assumed that the input torque Ti to the steering system via the motor 10 is determined with the following formula which adds the basic assist torque To proportional to the steering torque, the first correction torque Ta proportional to the rotation angular acceleration of the steering wheel 2, and the second correction torque Tb proportional to the change acceleration of the steering torque.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=Kw·d2θh/dt2
Th=Kdd·d2Ks(θh−θp)/dt
Ka is a basic assist control gain, Kw is a control gain of the steering angular velocity differentiation (steering angle second order differentiation), and Kdd is a torque second order differentiation control gain.
In the frequency response characteristic shown in
ω1={K/(Jp−Kw)}1/2 (13)
ζ1=Cp/[2{(Jp−Kw)·α1/α2}1/2] (14)
In the frequency response characteristic shown in
ω2=[{Ks(1+Ka)+K}/(Jp+Kdd)]1/2 (15)
ζ2=Cp/[2·{(Jp+Kdd)·Ks/α1}1/2] (16)
α1 is a parameter of the weight of steering when the frequency is zero, and α2 is a transmission ratio of disturbance when the frequency is zero, and are represented by the following formulas.
α1=Ks·K/{Ks(1+Ka)+K}
α2=1/{(1+Ka)+K/Ks}
K is a elastic coefficient, Jp is a inertia of the pinion axis conversion in the steering system, and Cp is a pinion axis conversion viscosity coefficient in the steering system lower than the torsion bar 29.
In
In
As shown in
The relation set between the absolute value of the steering torque T and the first torque gain Gtc is stored as a table or an arithmetic expression for example, and the first torque gain Gtc corresponding to the determined steering torque T is calculated in a calculation part 32′. Regarding the relation between the absolute value of the steering torque T and the first torque gain Gtc, as shown in the calculation part 32′ of
Further, the relation set between the vehicle speed V and the first vehicle speed gain Gvc is stored as a table or an arithmetic expression for example, and the first vehicle speed gain Gvc corresponding to the determined vehicle speed V is calculated in a calculation part 33′. Regarding the relation between the vehicle speed V and the first vehicle speed gain Gvc, as shown in the calculation part 33′ of
The first correction current i1 is determined by multiplying the first torque gain Gtc and the first vehicle speed gain Gvc to the first correction reference current ic in the multiplication parts 34, 35. As a result, the relation set as shown in the calculation parts 31′, 32′, 33′ of
The second correction current i2 directly correlating with the change acceleration d2T/dt2 is determined as with the fourth embodiment.
The flowchart of
According to the fifth embodiment described above, board diagrams similar to the board diagrams representing the frequency response characteristic shown in
For example, the input torque Ti is determined with the following formulas.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=Km·d2θm/dt2
Tb=Kdd·d2Ks(θh−θp)/dt
Km is a control gain of the motor rotation angular velocity differentiation (motor rotation angle second order differentiation).
In the frequency response characteristic represented by the steering frequency and the amplitude ratio of the steering torque T relative to the steering angle θh, the frequency ω1 and damping ratio ζ1 are determined with the following formulas.
ω1={K/(Jp−Km)}1/2 (17)
ζ1=Cp/[2·{(Jp−Km)·α1/α2}1/2] (18)
In the frequency response characteristic represented by the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque, the frequency ω2 and damping ratio ζ2 are determined with the following formulas.
ω2=[{Ks·(1+Ka)+K}/(Jp−Km+Kdd)]1/2 (19)
ζ2=Cp/[2·{(Jp−Km+Kdd)·Ks/α1}1/2] (20)
Since the first correction current i1 is directly correlating with the rotation angular acceleration d2θm/dt2 of the motor 10 and the gain of such rotation angular acceleration d2θm/dt2 is Km, the frequency ω1 increases pursuant to the above-mentioned formula (17) when the output of the motor 10 is corrected. In other words, the dotted line after correction shifts relative to the solid line before correction in
Since the second correction current i2 is directly correlating with the change acceleration d2T/dt2 of the steering torque T and the gain of such change acceleration d2T/dt2 is Kdd, the frequency ω2 decreases pursuant to the above-mentioned formula (19) when the output of the motor 10 is corrected. In other words, the dotted line after correction shifts relative to the solid line before correction in
Incidentally, although the foregoing formula (19) includes the gain Km, the frequency ω2 after the correction can be made smaller than before the correction by making the gain Kdd larger than the gain Km. The first relation between the rotation angular acceleration d2θm/dt2 of the motor 10 and the first correction current i1, and the second relation between the change acceleration d2T/dt2 and the second correction current i2 are set such that the frequency ω2 after the correction becomes smaller than before the correction. In this case, since the foregoing formula (17) does not include the gain Kdd, the frequency ω2 after the correction can be made smaller than before the correction even upon setting such first and second relations.
The first correction current i1 directly correlating with the rotation angular acceleration d2θh/dt2 of the steering wheel 2 is determined as with the fourth embodiment.
As shown in
The relation set between the steering torque T and the second torque gain Gtd is stored as a table or an arithmetic expression for example, and the second torque gain Gtd corresponding to the determined steering torque T is calculated in a calculation part 37′. Regarding the relation between the absolute value of the steering torque T and the second torque gain Gtd, as shown in the calculation part 37′ of
Further, the relation set between the vehicle speed V and the second vehicle speed gain Gvd is stored as a table or an arithmetic expression for example, and the second vehicle speed gain Gvd corresponding to the determined vehicle speed V is calculated in a calculation part 38′. Regarding the relation between the vehicle speed V and the second vehicle speed gain Gvd, as shown in the calculation part 38′ of
The second correction current i2 is determined by multiplying the second torque gain Gtd and the second vehicle speed gain Gvd to the second correction reference current id in the multiplication parts 39, 40. As a result, the relation set as shown in the calculation parts 36′, 37′, 38′ of
The flowchart of
According to the sixth embodiment described above, board diagrams similar to the board diagrams representing the frequency response characteristic shown in
For example, the input torque Ti is determined with the following formulas.
Ti=To+Ta+Tb
To=Ka·Ks(θh−θp)
Ta=Kw·d2θh/dt2
Tb=Km·d2θm/dt2
In the frequency response characteristic represented by the steering frequency and the amplitude ratio of the steering torque T relative to the steering angle θh, the frequency ω1 and damping ratio ζ1 are determined with the following formulas.
ω1={K/(Jp−Kw−Km)}1/2 (21)
ζ1=Cp/[2·{(Jp−Kw−Km)·α1/α2}1/2] (22)
In the frequency response characteristic represented by the input frequency (Hz) of the disturbance torque and the amplitude ratio of the steering torque T relative to the disturbance torque, the frequency ω2 and damping ratio ζ2 are determined with the following formulas.
ω2=[{Ks·(1+Ka)+K}/(Jp−Km)]1/2 (23)
ζ2=Cp/[2·{(Jp−Km)·Ks/α1}1/2] (24)
Since the first correction current i1 is directly correlating with the rotation angular acceleration d2θh/dt2 of the steering wheel 2 and the gain of such rotation angular acceleration d2θh/dt2 is Kw, the frequency ω1 increases pursuant to the above-mentioned formula (21) when the output of the motor 10 is corrected. In other words, the dotted line after correction shifts relative to the solid line before correction in
Since the second correction current i2 is inversely correlating with the rotation angular acceleration d2θm/dt2 of the motor 10 and the gain of such rotation angular acceleration d2θm/dt2 is Km, the frequency ω2 decreases pursuant to the above-mentioned formula (23) when the output of the motor 10 is corrected. In other words, the dotted line after correction shifts relative to the solid line before correction in
Incidentally, although the foregoing formula (21) includes the gain Km, the frequency ω1 after the correction can be made larger than before the correction by making the gain Kw larger than the gain Km. The first relation between the rotation angular acceleration d2θh/dt2 of the steering wheel 2 and the first correction current i1, and the second relation between the rotation angular acceleration d2θm/dt2 of the motor 10 and the second correction current i2 are set such that the frequency ω2 after the correction becomes larger than before the correction. In this case, since the foregoing formula (23) does not include the gain Kw, the frequency ω2 after the correction can be made smaller than before the correction even upon setting such first and second relations.
The present invention is not limited to the foregoing embodiments. For example, a sensor for determining the rotation angle θp of the pinion 5 can be provided when the rotation angular velocity of the pinion 5 is determined as the rotation angular velocity correspondence value corresponding to the rotation angular velocity of the motor 10. Or, a sensor for determining the rotation angle θp of the pinion 5 can be provided when the rotation angular acceleration of the pinion 5 is determined as the rotation angular acceleration correspondence value corresponding to the rotation angular acceleration of the motor 10. Further, sensors for determining the inter-terminal voltage of the motor 10 and motor current can be provided when the rotation angle per unit time of the motor 10 is determined from the determined values and known arithmetic expressions. The mechanism for transmitting the rotation of the steering wheel to the vehicle wheels so as to vary the steering angle is not limited to the embodiments, and the rotation of the steering wheel can be transmitted to the vehicle wheels from the steering shaft via a mechanism such as a linkage other than the rack and pinion. Further, the transmission mechanism for transmitting the output of the motor for generating the steering assist power to the steering system is not limited to the embodiments so as long as it is able to apply such steering assist power, for instance, the steering assist power can be applied by transmitting the motor output to a ball nut screwed to a ball screw that is formed integrally with the rack.
Number | Date | Country | Kind |
---|---|---|---|
2004-37324 | Feb 2004 | JP | national |
2004-37235 | Feb 2004 | JP | national |