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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to an electric power steering
apparatus which provides power assist of an electric motor directly to a
steering system so as to reduce necessary steering power to be applied by
the driver. More particularly, it relates to such an electric power
steering apparatus which is capable of providing the power assist even
when operation of a sensor such as a motor current detector becomes
abnormal.
2. Description of the Related Art
FIG. 4 of the accompanying drawings shows in block diagram the general
construction of a control unit 120 of a conventional electric power
steering apparatus.
The conventional control unit 120 generally includes a target current
calculating section 121, a target current correcting section 122, a
feedback (F/B) control section 123, a motor driving section 124, a motor
speed calculating section 125, a sensor fault detecting section 126, and a
fault indicating section or indicator 127.
The target current calculating section 121 determines a target assist
torque on the basis of a steering torque signal Tp supplied from a
steering torque sensor 112 and outputs a signal (hereinafter referred to
as "target current") IT corresponding to a target current value required
for an electric motor 110 to apply the target assist torque to a steering
system. The target current IT is supplied to the target current correcting
section 122.
The target current correcting section 122 calculates and outputs a signal
(hereinafter referred to as "corrected target current") ITH corresponding
to a corrected target current value resulting from a correction made to
the target current IT on the basis of a steering angle signal 114a
supplied from a steering angle sensor 114, a vehicle velocity signal 116a
supplied from a vehicle velocity sensor 116, yaw rate signal 118a supplied
from a yaw rate sensor 118, and a motor speed signal 125a determined by
calculation at a motor speed calculating section 125 to meet the current
vehicle running conditions such as the steering condition, vehicle
velocity, and yaw rate, and the rotational speed of an electric motor 110.
The corrected target current ITH is supplied to the feedback control
section 123.
The feedback control section 123 includes an offset calculating part 131
and a PID (proportional and integral and derivative) control part or
controller 132. The offset calculating part 131 determines an offset
between the corrected target current ITH and a signal (hereinafter
referred as "motor current") IM corresponding to a motor current detected
by a motor current detecting unit or detector 128, and outputs an offset
signal 131a representing the determined offset (ITH-IM). The offset signal
131a is supplied to the PID controller 132. The PID controller 132 applies
PID arithmetic processing to the offset signal 131a to generate a drive
control signal 132a which controls a current to be supplied to the
electric motor 110 so as to render the offset (ITH-IM) zero. The drive
control signal 132a is supplied to the motor drive section 124.
The motor drive section 124 includes a PWM (pulse-width modulation) signal
generating part or generator 141, a gate drive circuit 142, and a motor
drive circuit 143 consisting of four power FETs (field-effect transistors)
connected in an H-type bridge. The PWM signal generator 141 generates, on
the basis of the drive control signal 132a, a PWM signal 141a for
PWM-driving the electric motor 110. The PWM signal 141a is supplied to the
gate drive circuit 142. The gate drive circuit 142 drives the gates of the
FETs and thereby drives switching of the FETs on the basis of the PWM
signal 141a. Thus, the control unit 120 PWM-controls power supplied from a
battery power source BAT to the electric motor 110 on the basis of the
steering torque Tp detected by the steering torque sensor 112 and thereby
control the output power (steering assist force or torque) of the electric
motor 110.
The motor speed calculating section 125 calculates a rotational speed of
the electric motor 110 on the basis of the motor current IM detected by
the motor current detector 128 and a signal (hereinafter referred to as
"motor voltage") VM corresponding to a motor voltage detected by a motor
voltage detecting unit or detector 129, and outputs a motor speed signal
125a corresponding to the calculated rotational speed of the electric
motor 110.
The sensor fault detecting section 126 monitors the steering angle signal
114a, the vehicle velocity signal 116a, the yaw rate signal 118a, the
motor speed signal 125a, the motor current IM and the motor voltage VM.
When any one of the signals 114a, 116a, 118a, 125a, IM and VM is outside a
predetermined range of signal value set in advance for each signal, when
any one of the signals 114a, 116a, 118a, 125a, IM and VM is not supplied
from the corresponding sensor or detector, or when any one of the signals
114a, 116a, 118a, 125a, IM and VM varies abnormally, the sensor fault
detecting section 126 judges the sensor (detector) 114, 116, 118, 125, 128
or 129 to be operating abnormally and outputs a sensor fault detection
signal 126a. The sensor fault detecting section 126 is constructed to
store detection of a sensor fault in a nonvolatile memory so that the
sensor fault detection signal 126a is automatically output when the power
is turned on at the next operation the control unit 120. The sensor fault
detection signal 126a is supplied to the motor drive section 124 and the
fault indicator 127.
Upon receipt of the sensor fault detection signal 126a, the motor drive
section 124 stops the PWM signal generating operation or the gate driving
operation, or opens contacts of a relay (not shown) disposed between the
battery power source BAT and the motor drive circuit 143, thereby stopping
operation of the electric motor 110.
The fault indicator 127 is an indicator that upon receipt of the sensor
fault detection signal 126a, provides an instantaneous alarm, both visual
and audible, of a failure detected in the sensor to thereby indicate that
a failure arises in the sensors and the electric power steering apparatus
is in the inoperative condition due to the failure in the sensor.
However, in the conventional electric power steering apparatus having the
control unit 120 shown in FIG. 4, when the motor current detector 128
provided for the feedback control of operation of the electric motor 110
or another sensor provided to generate a signal for the correction of a
steering assist torque in accordance with running conditions of the
vehicle becomes anomalous in operation, or when a sensor's operation
failure is detected in error, because supply of the steering assist force
from the electric motor 110 is suddenly stopped, the steering wheel
becomes suddenly heavy, and this may be disconcerting for the driver.
To avoid these difficulties caused by sudden stop of the supply of steering
assist force, it may be considered that two sets of sensors are provided
so that when one set of sensors becomes faulty, operation of the control
unit can be continued based on information from the other set of sensors.
Such fail-safe system, however, will increase the number of components
needed and the cost of the vehicle.
SUMMARY OF THE INVENTION
It is accordingly an object of the present invention to provide an electric
power steering apparatus which can continue operation of an electric motor
to supply a steering assist force or torque even when a motor current
detector provided for feedback control of the electric motor or another
sensor provided for supplying information to correct the assist steering
torque is operating abnormally.
According to the present invention, there is provided an electric power
steering apparatus for a vehicle, comprising: an electric motor for
applying a steering assist torque to a steering system operatively
connecting a steering wheel and steerable wheels of the vehicle; a
steering torque sensor for detecting a steering torque of the steering
system and outputting a steering torque signal corresponding to the
detected steering torque; a target current calculating section for
calculating, on the basis of at least the steering torque signal, a target
current to be supplied to the electric motor and outputting a target
current signal corresponding to the calculated target current; a motor
current detector for detecting a current flowing in the electric motor and
outputting a motor current signal corresponding to the detected current;
an offset calculating section for calculating an offset between the target
current signal and the motor current signal and outputting an offset
signal corresponding to the calculated offset; a first drive control
signal generating section for generating, on the basis of the offset
signal, a first drive control signal to drive the electric motor; a second
drive control signal generating section for generating, on the basis of
the target current signal, a second drive control signal to drive the
electric motor; a fault defecting section for detecting abnormality in the
electric power steering apparatus; and a motor drive control mode
switching section for changing over drive control modes of the electric
motor such that when abnormality in the apparatus is not detected by the
fault detecting section, operation of the electric motor is controlled on
the basis of the first drive control signal, and when abnormality in the
apparatus is detected by the fault detecting section, operation of the
electric motor is controlled on the basis of the second drive control
signal.
The fault detecting section detects a failure in said motor current
detector.
In the electric power steering apparatus, when abnormality in the
apparatus, such as a failure of the motor current detector, is not
detected, the electric motor is feedback-controlled on the basis of the
first drive control signal in such a manner that an offset between the
target current signal set in accordance with the steering torque and the
motor current signal is rendered zero. Thus, a steering assist torque
corresponding to the steering torque is supplied from the electric motor
to the steering system.
When abnormality of the apparatus, such as a failure of the motor current
detector, is detected, the electric motor is feedforward-controlled on the
basis of the second drive control signal generated on the basis of the
target current signal set in accordance with the steering torque. Thus, a
steering assist torque corresponding to the steering torque is supplied
from the electric motor to the steering system.
The electric power steering system according to the present invention can
continue supply of a steering assist torque from the electric motor to the
steering system even when operation failures in various sensors are
detected. The apparatus is, therefore, free from the problem that when
supply of the steering assist torque is suddenly stopped, the steering
wheel becomes heavy, thereby disconcerting the driver and deteriorating
the steerability of the vehicle.
The above and other objects, features and advantages of the present
invention will become manifest to these versed in the art upon making
reference to the detailed description and the accompanying sheets of
drawings in which preferred structural embodiments incorporating the
principles of the invention are shown by way of illustrative examples.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagrammatical view showing the general construction of an
electric power steering apparatus;
FIG. 2 is a block diagram showing a control unit of the electric power
steering apparatus according to a first embodiment of the present
invention;
FIG. 3 is a block diagram showing a control unit of the electric power
steering apparatus according to a second embodiment of the present
invention; and
FIG. 4 is a block diagram showing a control unit of a conventional electric
power steering apparatus.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Certain preferred embodiments of the present invention will be described
below in greater detail with reference to the accompanying drawings,
wherein like reference characters designate like or corresponding parts
throughout several views.
Referring to FIG. 1, there is shown the general construction of an electric
power steering apparatus 1 according to the present invention. The
electric power steering apparatus 1 includes a steering system equipped
with an electric motor 10 and operatively connecting a steering wheel 2
and steerable from wheels 9, 9 of a vehicle, and a control unit 20 for
controlling the output power of the electric motor 10 so as to reduce
manual steering effort or force to be applied by the driver to turn the
steering wheel 2.
The steering system includes a steering column or shaft 3 connected at one
end to the steering wheel 2. The opposite end of the steering shaft 3 is
connected by a connecting shaft 4 having universal joints 4a, 4b to a
pinion 6 of a rack-and-pinion mechanism 5. The pinion 6 meshes with a rack
of gear teeth 7a on a rack shaft 7. The rack-and-pinion mechanism 5
converts rotation of the pinion 6 into axial reciprocating motion of the
rack shaft 7. The steerable right and left front wheels 9 are connected to
the opposite ends of the rack shaft 7 via tie rods 8. When the steering
wheel 2 is turned, the front wheels 9 are caused to pivot by way of the
rack-and-pinion mechanism 5 and the tie rods 8. In this way it is possible
to change the direction of the vehicle.
In order to reduce the manual steering effort or force that must be exerted
by the driver, the electric motor 10 for supplying a steering assist
torque is disposed concentrically with the rack 7 and a rotational output
of the electric motor 10 is converted into a thrust force and made to act
on the rack shaft 7 via a ball screw mechanism 11 mounted substantially
parallel with the rack 7. The electric motor 10 has a rotor equipped with
a drive helical gear 10a which is in mesh with a driven helical gear 11b
attached to an end of a screw shaft 11a of the ball screw mechanism 11. A
nut 11c of the ball screw mechanism 11 is connected to the rack 7.
A steering torque detecting device (steering torque sensor) 12 is disposed
in a steering box (not shown) for detecting a manual steering torque Ts
acting on the pinion 6. The steering torque sensor 12 supplies a steering
torque signal Tp corresponding to the detected steering torque Ts, to the
control unit 20. The control unit 20 operates the electric motor 10 on the
basis of the steering torque signal Tp taken as a main signal and thereby
controls the output power (steering assist torque) of the electric motor
10.
FIG. 2 shows in block diagram the arrangement of a first embodiment of the
control unit 20 according to the present invention.
As shown in FIG. 2, the control unit 20 includes a target current
calculating section 21, a target current correcting section 22, a feedback
(F/B) control section 23 forming a first drive signal generating section
or generator, a second drive signal generating section or generator 50, a
motor drive control mode switching section 51, a motor drive section 24, a
motor current calculating section 25, a sensor fault detecting section 26
forming a fault detecting section, and a fault indicating section or
indicator 27. The control unit 20 differs from the conventional control
unit 120 shown in FIG. 4 in that the second drive control signal generator
50 and the motor drive control mode switching section 51 are added.
The target current calculating section 21 determines a target assist torque
on the basis of a steering torque signal Tp supplied from the steering
torque sensor 12 and outputs a signal (hereinafter referred to as "target
current") IT corresponding to a target current value required for the
electric motor 10 to supply the target assist torque to the steering
system. The target current IT is supplied to the target current correcting
section 22.
The target current correcting section 22 calculates and outputs a signal
(hereinafter referred to as "corrected target current") ITH corresponding
to a corrected target current value resulting from the target current IT
corrected the basis of a steering angle signal 14a supplied from a
steering angle sensor 14, a vehicle velocity signal 16a supplied from a
vehicle velocity sensor 16, a yaw rate signal 18a supplied from a (vehicle
body) yaw rate sensor 18, and a motor speed signal 25a determined by
calculation at the motor speed calculating section 25 so as to meet the
current vehicle running conditions including the steering condition,
vehicle velocity and raw rate, and the rotational speed of the electric
motor 10. The corrected target current ITH is supplied to the feedback
control section 23.
The feedback control section 23 includes an offset calculating part 31 and
a PID (proportional and integral and derivative) control part or
controller 32. The offset calculating part 31 determines an offset between
the corrected target current ITH and a signal (hereinafter referred as
"motor current") IM corresponding to a motor current detected by a motor
current detecting unit or detector 28, and outputs an offset signal 31a
representing the determined offset (ITH-IM). The offset signal 31a is
supplied to the PID controller 32. The PID controller 32 applies PID
arithmetic processing to the offset signal 31a to generate a drive control
signal 32a which controls a current to be supplied to the electric motor
10 in order to make the offset (ITH-IM) approach zero. The drive control
signal 32a is supplied to the motor drive section 24 through the motor
drive control mode switching section 51.
The motor drive section 24 includes a PWM (pulse-width modulation) signal
generating part or generator 41, a gate drive circuit 42, and a motor
drive circuit 43 consisting of four power FETs (field-effect transistors)
connected in an H-type bridge. The PWM signal generator 41 generates, on
the basis of the drive control signal 32a, a PWM signal 41a for
PWM-driving the electric motor 10. The PWM signal 41a is supplied to the
gate drive circuit 42. The gate drive circuit 42 drives the gates of the
FETs and thereby drives switching of the FETs on the basis of the PWM
signal 41a. Thus, the control unit 20 PWM-controls power supplied from a
battery power source BAT to the electric motor 10 on the basis of the
steering torque Tp detected by the steering torque sensor 12 and thereby
control the output power (steering assist torque) of the electric motor
10.
The motor speed calculating section 25 calculates a rotational speed of the
electric motor 10 on the basis of the motor current IM detected by the
motor current detector 28 and a signal (hereinafter referred to as "motor
voltage") VM corresponding to a motor voltage detected by a motor voltage
detecting unit or detector 29, and outputs a motor speed signal 25a
corresponding to the calculated rotational speed of the electric motor 10.
The sensor fault detecting section 26 monitors the steering angle signal
14a, the vehicle velocity signal 16a, the yaw rate signal 18a, the motor
speed signal 25a, the motor current IM and the motor voltage VM. When any
one of the signals 14a, 16a, 18a, 25a, IM and VM is outside a
predetermined range of signal value set in advance for each signal, when
any one of the signals 14a, 16a, 18a, 25a, IM and VM is not supplied from
the corresponding sensor or detector, or when any one of the signals 14a,
16a, 18a, 25a, IM and VM varies abnormally, the sensor fault detecting
section 26 judges the sensor (detector) 14, 16, 18, 25, 28 or 29 to be
operating abnormally or at fault and outputs a sensor fault detection
signal 26a. The sensor fault detecting section 26 is constructed to store
detection of a sensor fault in a nonvolatile memory so that the sensor
fault detection signal 26a is automatically output when the power is
turned on at the next operation of the control unit 20. The sensor fault
detection signal 26a is supplied to the motor drive section 24 and the
fault indicator 27.
The fault indicator 27 is an indicator that upon receipt of the sensor
fault detection signal 26a, provides an instantaneous alarm, both visual
and audible, of a failure detected in the sensor to thereby indicate that
a failure arises in the sensors and the electric power steering apparatus
is in the inoperative condition due to the failure in the sensor.
The second drive control signal generator 50 generates a second drive
control signal 50a on the basis of the target current signal IT output
from the target current calculating section 21, and outputs the second
drive control signal 50a to the motor drive section 24 through the motor
drive control mode switching section 51.
The motor drive control mode switching section 51, when it is supplied with
the sensor fault detection signal 26a from the sensor fault detecting
section 26, supplies the first drive control signal 32a from the PID
controller 32 to the PWM signal generator 41. Alternately, when it is
supplied with the sensor fault detection signal 26a, the motor drive
control mode switching section 51 operates to changeover the first drive
control signal 32a to the second drive control signal 50a and supplies the
second drive control signal 50a to the PWM signal generator 41.
Accordingly, when the motor current detector 28, the motor voltage detector
29, the steering angle sensor 14, the vehicle velocity sensor 16, and the
yaw rate sensor 18 are operating normally, the motor current IM supplied
to the electric motor 10 on the basis of the correct target current ITH is
feedback-controlled. When any one of the sensors (detectors) 28, 29, 14,
16, 18 becomes anomalous in operation, operation of the electric motor 10
is feedforward-controlled on the basis of the second drive control signal
50a generated based on the target current IT.
The second drive control signal generator 50 outputs a 50 to 80 percent
value, for example, of the target current IT as the second drive control
signal 50a. Because a smaller value than the target current IT is output
as the second second drive control signal 50a, the steering assist torque
supplied from the electric motor 10 is reduced to thereby allow the driver
to notify an abnormal condition in which the steering assist torque is not
correctly supplied (or the control unit 20 is operating abnormally). Under
the feedforward control of the electric motor 10 performed based on the
second drive control signal 50a, the current supplied to the electric
motor 10 may increase extraordinarily with a sudden increase in the
steering torque Tp, for example. To cope with this problem, a gain of the
second drive control signal generator 50 is set to be small enough to
prevent the steering assist torque supplied from the electric motor 10
from varying extraordinarily with changes in the steering torque Tp.
As described above, because when an operation failure in any of the sensors
28, 29, 14, 16, 18 is detected by the sensor fault detecting section 26,
operation of the electric motor 10 is controlled on the basis of the
second drive control signal 50a generated by the second drive control
signal generator 50, the control unit 20 can operate the electric motor 10
to supply a steering assist torque the steering system on the basis of the
steering torque even though the sensor is operating abnormally. Thus, the
driver is not disconcerted by a sudden stop of the supply of the steering
assist force. By virtue of the steering assist torque continuously
supplied in correspondence with the steering torque Tp without regard to
the failure detected in the sensor, the steering wheel can be turned
lightly and smoothly even when the vehicle is steering for parking.
Reference is made to FIG. 3 which shows in block diagram the construction
of a control unit 20A according to a second embodiment of the present
invention.
As shown in FIG. 3, the control unit 20A comprises a target current
calculating section 21, a target current correcting section 70, a feedback
(F/B) control section 23 constituting a first drive signal generating
section or generator, a second drive signal generating section or
generator 60, a motor drive control mode switching section 61, a motor
drive section 24, a motor current calculating section 25, a sensor fault
detecting section 71 constituting a fault detecting section, and a fault
indicating section or indicator 72.
The sensor fault detecting section 71 monitors a steering angle signal 14a
supplied from a steering torque sensor 12, a vehicle velocity signal 16a
supplied from a vehicle velocity sensor 16, a yaw rate signal 18a supplied
from a yaw rate sensor 18, a motor speed signal 25a supplied from the
motor speed calculating section 25, a motor current IM detected by a motor
current detector 28, and a motor voltage VM detected by a motor voltage
sensor 29. When any one of the signals 14a, 16a, 18a, 25a, IM and VM is
outside a predetermined range of signal value set in advance for each
signal, when any one of the signals 14a, 16a, 18a, 25a, IM and VM is not
supplied from the corresponding sensor or detector, or when any one of the
signals 14a, 16a, 18a, 25a, IM and VM varies abnormally, the sensor fault
detecting section 71 judges the sensor (detector) 14, 16, 18, 25, 28 or 29
to be operating abnormally or at fault and outputs faulty sensor
identification information 71a. The faulty sensor identification
information 71a is supplied to the fault indicator 72 and the target
current correcting section 70.
The sensor fault detecting section 71, when it detects anomaly in operation
of the motor current detector 28, outputs a drive control mode changeover
signal 71b. The drive control mode changeover signal 71b is supplied to
the motor drive control mode switching section 61.
The fault indicator 72 is an indicator that upon receipt of the faulty
sensor identification information 71a, provides an instantaneous alarm,
both visual and audible, to identify which sensor is operating abnormally.
For instance, when an operation failure in the vehicle velocity sensor 16
is detected by the sensor fault detecting section 71, the fault indicators
72 indicates the vehicle velocity sensor 16 operating abnormally.
Similarly, when an operation failure of the motor current detector 28 is
detected by the sensor fault detecting section 71, the fault indicator 72
indicates the vehicle velocity sensor 16 operating abnormally.
The target current correcting section 70, when it is not supplied with the
faulty sensor identification information 71a, calculates and outputs a
corrected target current ITH resulting from a target current IT corrected
on the basis of the steering angle signal 14a, the vehicle velocity signal
16a, the yaw rate signal 18a, and the motor speed signal 25a, so as to
meet the current vehicle running conditions including the steering
condition, vehicle velocity and yaw rate, and the rotational speed of the
electric motor 10.
The target current correcting section 70, when it finds the steering angle
sensor 14 abnormal in operation on the basis of the faulty sensor
identification information 71a, stops target current correcting operation
based on the steering angle. Similarly, when the faulty sensor
identification information 71a makes the target current correcting section
70 acknowledge the vehicle velocity sensor 16 operating abnormally, the
target current correcting section 70 performs a correction to reduce the
target current IT on the assumption that the vehicle is running at a
maximum speed. Alternatively, when an operation failure in the yaw rate
sensor 18 is acknowledged by the target current correcting section 70 on
the basis of the faulty sensor identification information 71a, the target
current correcting section 70 stops target current correcting operation
based on the yaw rate of the vehicle body, or performs a correction to
lower the target current IT on the assumption that the yaw rate is at a
maximum. Similarly, the faulty sensor identification information 71a makes
the target current correcting section 70 to acknowledge the motor current
detector 28 or the motor voltage detector 29 to be in an abnormally
operating condition, the target current correcting section 70 stops
correction of the target current IT based on the motor speed 25a
calculated by the motor speed calculating section 25.
Thus, instead of performing correction of the target current correcting
section 70 based on the signal supplied from a faulty sensor (or further
to a fail-safe operation performed on the correction the target current IT
on the basis of the faulty sensor's signal), the target current correcting
section 70 performs corrections of the signals supplied from the remaining
sensors (normally operating sensors) and outputs the results of
corrections as a corrected target current ITH. The corrected target
current ITH is supplied to the feedback control section (first drive
control signal generator) 23 and the second drive control signal generator
60.
The feedback control section (first drive control signal generator) 23
generates and outputs a first drive control signal 32a as a result of PID
control applied to an offset between the corrected target current ITH
which has been corrected on the basis of the signals from the normally
operating sensors, and the motor current IM in such a manner that the
offset approaches zero.
The second drive control signal generator 60 generates a second drive
control signal 60a on the basis of the corrected target current ITH which
has been corrected on the basis of the signals from the normally operating
sensors. The second drive control signal generator 60 is so constructed as
to output a 50 to 80 percent value of the corrected target current ITH.
The motor drive control mode switching section 61, when the drive control
mode changeover signal 71b is not supplied to it, allows the first drive
control signal 32a output from the feedback control section 23 to be
supplied to the motor drive section 24. When the drive control mode
changeover signal 71b is supplied to the motor drive control mode
switching section 61, the motor drive control mode switching section 61
allows the second drive control signal 60a output from the second drive
control signal generator 60 to be supplied to the motor drive section 24.
In the control unit 20A of the second embodiment shown in FIG. 3, when the
sensors are operating normally, a target current IT is set by the target
current calculating section 21 on the basis of a steering torque Tp
detected by the steering torque sensor 12, then a corrected target current
ITH is generated by the target current correcting section 70 as a result
of correction made on the target current IT on the basis of running
conditions of the vehicle and the rotational speed of the electric motor
10, and operation of the electric motor 10 is feedback-controlled by the
feedback control section in such a manner that an offset between the
corrected target current ITH and a motor current IM approaches zero.
When any of the sensors becomes anomalous in operation, operation of the
electric motor 10 is controlled on the basis of the second drive control
signal 60a. Because the second drive control signal generator 60 generates
this second drive control signal 60a on the basis of the corrected target
current ITH, when the steering angle sensor 14, the vehicle velocity
sensor 16 and the yaw rate sensor 18 are operating normally, the electric
motor 10 is controlled in operation by a corrected target current ITH
obtained as a result of correction of the target current IM made on the
basis of the signals supplied from these sensors 14, 16, 18.
In the case where an operation failure arises in one of the steering angle
sensor 14, the vehicle velocity sensor 16 and the yaw rate sensor 18 while
the motor current detector 28 is operating normally, correction of the
target current on the basis of the faulty sensor's signal is stopped (or
replaced with a fail-safe operation thereof) and, at the same time,
feedback control based on the offset between a corrected target current
ITH resulting from the target current corrected on the basis of the
normally operating sensor's signals and the motor current IM.
Accordingly, even when a failure arises in the motor current detector 28,
supply of the steering assist torque from the electric motor 10 to the
steering system can still be continued. When any one of the steering angle
sensor 14, the vehicle velocity sensor 16 and the yaw rate sensor 18
becomes abnormal in operation, operation of the electric motor 10 is
feedback-controlled while the target current IT is being corrected on the
basis of the outputs from the remaining sensors operating normally.
In the control unit 20 of the second embodiment shown in FIG. 3, the target
current calculating section 21 and the target current correcting section
70 may be arranged to jointly form a target current calculating section
that determines, by calculation on the basis of at least the steering
torque signal Tp, a target current to be supplied to the electric motor 10
and outputs a target current signal corresponding to the determined target
current.
Additionally, although in the control unit 20 of the first embodiment shown
in FIG. 2 a target current IT calculated by the target current calculating
section 21 is supplied to the second drive control signal generator 50 to
generate a second drive control signal 50a, the target current correcting
section 70 and the sensor fault detecting section 71 of the second
embodiment shown in FIG. 3 may be incorporated in the control unit 20 so
that the second drive control signal is generated on the basis of the
corrected target current ITH.
Obviously, various minor changes and modifications are possible in the
light of the above teaching. It is to be understood that within the scope
of the appended claims the present invention may be practiced otherwise
than as specifically described.
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