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References  |
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U.S. References |
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| | Reference | Relevancy | Comments | Reference | Relevancy | Comments | 5907298
Kiriyama et al.
May,1999 |  Your vote accepted
[0 after 0 votes] | | 5731681
Inaniwa et al.
Mar,1998 | Your vote accepted
[0 after 0 votes] | | 5694015
Luniewicz et al.
Dec,1997 | Your vote accepted
[0 after 0 votes] | | 5533166
Yoshida et al.
Jul,1996 | Your vote accepted
[0 after 0 votes] | | 5495161
Hunter
Feb,1996 | Your vote accepted
[0 after 0 votes] | | 5467004
Matsuo et al.
Nov,1995 | Your vote accepted
[0 after 0 votes] | | 5433541
Hieda et al.
Jul,1995 | Your vote accepted
[0 after 0 votes] | | 5367241
Lee et al.
Nov,1994 | Your vote accepted
[0 after 0 votes] | | 5325460
Yamada et al.
Jun,1994 | Your vote accepted
[0 after 0 votes] | | 5140245
Stacey
Aug,1992 | Your vote accepted
[0 after 0 votes] | | 5010287
Mukai et al.
Apr,1991 | Your vote accepted
[0 after 0 votes] | | 4893066
Stewart et al.
Jan,1990 | Your vote accepted
[0 after 0 votes] | | 4808902
Miyazaki et al.
Feb,1989 | Your vote accepted
[0 after 0 votes] | | 4795950
Ota et al.
Jan,1989 | Your vote accepted
[0 after 0 votes] | | 4772838
Maresca
Sep,1988 | Your vote accepted
[0 after 0 votes] | | 4689539
Unno et al.
Aug,1987 | Your vote accepted
[0 after 0 votes] | | 4680518
Kurakake et al.
Jul,1987 | Your vote accepted
[0 after 0 votes] | | 4621224
Watabe et al.
Nov,1986 | Your vote accepted
[0 after 0 votes] | | 4588936
Itoh et al.
May,1986 | Your vote accepted
[0 after 0 votes] | | 4489267
Saar et al.
Dec,1984 | Your vote accepted
[0 after 0 votes] | | 4357569
Iwakane et al.
Nov,1982 | Your vote accepted
[0 after 0 votes] | | 4361792
Davis, Jr. et al.
Nov,1982 | Your vote accepted
[0 after 0 votes] | | 4358726
Iwakane et al.
Nov,1982 | Your vote accepted
[0 after 0 votes] | | 3829747
Woolfson et al.
Aug,1974 | Your vote accepted
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Other References |
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References |
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Claims |
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What is claimed is:
1. A controller for an electric motor, comprising:
a reference circuit which generates a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit; and
control circuitry, which receives the reference signal and receives a feedback signal from a rotation detector coupled to the motor, the detector having an inherent angular rotational resolution, and compares the reference signal and the feedback
signal to generate a drive signal used to drive the motor at a speed and phase of rotation determined by the frequency and phase of the reference signal,
the phase of rotation of the motor being locked to the phase of the reference signal such that deviation of the phase of rotation relative to the phase of the reference signal at steady state is substantially smaller than the rotational
resolution of the rotation detector,
wherein the control circuitry comprises a first phase-frequency comparator, which generates a phase-frequency signal responsive to the deviation between the phase of the reference and the phase of rotation of the motor, and wherein the
phase-frequency signal is processed to generate the drive signal, and
wherein the control circuitry comprises an integration circuit, which receives and integrates the phase-frequency signal to generate a modified phase-frequency signal, responsive to the phase-frequency signal and the feedback signal, wherein the
modified phase-frequency signal is characterized by a second-order astatism.
2. A controller according to claim 1, wherein the integration circuit comprises a second phase-frequency comparator.
3. A controller according to claim 1, wherein the reference signal and the control circuitry receive a first clock signal, and generate the reference and phase-frequency signals responsive thereto, and wherein the integration circuit receives a
second clock signal, asynchronous with the first clock signal, and uses the second clock signal to generate the modified phase-frequency signal.
4. A controller according to claim 1, and further comprising an additional integration circuit, which receives and integrates the modified phase-frequency signal to generate a further modified phase-frequency signal characterized by a third or
higher order astatism.
5. A controller according to claim 1, wherein the modified phase-frequency signal comprises a pulse-width modulated signal.
6. A controller according to claim 1, wherein the control circuitry comprises a pulse add-remove circuit, which combines the reference and feedback signals to provide a sequence of pulses, which is processed to provide an input to the
phase-frequency comparator, such as to enable continuous control of the operation of the motor when it rotates at a speed substantially lower than the reference speed.
7. A controller according to claim 6, wherein the motor rotates at a speed less than 10 rpm.
8. A controller according to claim 7, wherein the rotation speed is less than 1 rpm.
9. A controller according to claim 8, wherein the rotation speed is less than 0.1 rpm.
10. A controller for an electric motor, comprising:
a reference circuit which generates a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit;
control circuitry, which receives the reference signal and receives a feedback signal from a rotation detector coupled to the motor, and compares the reference signal and the feedback signal to generate a drive signal used to drive the motor at a
speed and phase of rotation determined by the frequency and phase of the reference signal,
such that when the frequency of the reference signal is changed to a new frequency thereof, the control circuitry generates the drive signal such that the speed of rotation of the motor changes to a new speed, determined by the new frequency,
substantially without overshoot or undershoot,
wherein the feedback signal is a periodic signal having a frequency and phase dependent on the rotation of the motor, and wherein the control circuitry comprises a phase-frequency comparator, which generates a signal responsive to a phase
deviation between the phase of the reference signal and the phase of rotation of the motor, wherein the signal is processed to generate the drive signal; and
an automatic phasing circuit, which controls the phase-frequency comparator responsive to a change in the motion parameters, so as to prevent the overshoot or undershoot,
wherein the phase-frequency comparator comprises an edge-controlled digital memory network, having a plurality of states, wherein the network makes transitions among the plurality of states responsive to the reference and feedback signals input
to the comparator, and wherein the signal generated by the comparator is dependent on the state of the network, and wherein the automatic phasing device controls the transitions among the states.
11. A controller according to claim 10, wherein the plurality of states comprises five states, having ten possible transitions therebetween.
12. A controller according to claim 10, wherein the five states comprise two saturation states, two work states and a zero state.
13. A controller for an electric motor, comprising:
a reference circuit which generates a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit; and
control circuitry, which receives the reference signal and receives a periodic feedback signal, having a frequency and phase dependent on the rotation of the motor, from a rotation detector coupled to the motor, and compares the reference signal
and the feedback signal to generate a drive signal used to drive the motor at a speed and phase of rotation determined by the frequency and phase of the clock signal,
the drive signal comprising a sequence of pulses having a pulse repetition frequency substantially higher than the frequency of the feedback signal,
wherein the sequence of pulses in the drive signal comprises a series of pulse bursts, wherein the number of pulses in each burst is generally dependent on a phase deviation between the phase of the reference and the phase of rotation of the
motor.
14. A controller for an electric motor, comprising:
a clock generator, which generates a clock signal having a substantially constant frequency;
a reference circuit which generates a reference signal responsive to the clock signal, having a phase and frequency determined in accordance with a set of motion parameters input to the circuit, such that the phase and frequency may be varied
substantially continuously in response to the motion parameters; and
control circuitry, which receives the reference signal and receives a feedback signal from a rotation detector coupled to the motor, and compares the reference signal and the feedback signal to generate a drive signal used to drive the motor at a
speed and phase of rotation determined by the frequency and phase of the reference signal,
wherein the reference circuit comprises one or more programmable frequency dividers and one or more programmable frequency multipliers, which receive the clock signal and the motion parameters and produce the reference signal, and
wherein at least one of the one or more dividers and at least one of the one or more multipliers are arranged in series, and
wherein the one or more multipliers and one or more dividers include two pairs of one multiplier and one divider each, each pair arranged in series, and the two pairs arranged mutually in parallel.
15. A controller for an electric motor, comprising:
a clock generator, which generates a clock signal having a substantially constant frequency;
a reference circuit which generates a reference signal responsive to the clock signal, having a phase and frequency determined in accordance with a set of motion parameters input to the circuit, such that the phase and frequency may be varied
substantially continuously in response to the motion parameters; and
control circuitry, which receives the reference signal and receives a feedback signal from a rotation detector coupled to the motor, and compares the reference signal and the feedback signal to generate a drive signal used to drive the motor at a
speed and phase of rotation determined by the frequency and phase of the reference signal,
wherein the reference circuit comprises a phase-frequency comparator and a pulse add-remove circuit, which adjust the reference signal responsive to a change in the set of motion parameters, so that the motor is driven to respond to the change
substantially continuously.
16. A controller for an electric motor, comprising:
a clock generator which generates first and second mutually asynchronous clock signals, each having a known phase and frequency;
a reference circuit which receives the first clock signal, and generates a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit; and
control circuitry, which receives the second clock signal and the reference signal and receives a feedback signal from a rotation detector coupled to the motor, and compares the reference signal and the feedback signal to generate a drive signal
based on the second clock signal, wherein the drive signal is used to drive the motor at a speed and phase of rotation determined by the frequency and phase of the reference signal.
17. A controller according to claim 16, wherein the phase of rotation of the motor is locked to the phase of the reference signal, immediately after the motor speed reaches the reference speed value, such that deviation of the phase of rotation
relative to the phase of the reference signal at steady state is substantially smaller than an inherent angular rotational resolution of the rotation detector.
18. A controller according to claim 16, wherein the control circuitry comprises a phase-frequency comparator, which uses the second clock signal to generate a phase-frequency signal responsive to the deviation between the phase of the reference
and the phase of rotation of the motor.
19. A controller according to claim 18, wherein the controlling circuitry comprises one or more duty cycle to phase frequency converters and one or more logic phase-frequency comparators, arranged in series, to generate the drive signal.
20. A controller according to claim 16, and further comprising a motor drive, which receives the drive signal from the control circuitry and drives the motor responsive thereto.
21. A method for controlling an electric motor, comprising:
generating a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit;
receiving a feedback signal from a rotation detector coupled to the motor, the detector having a predetermined rotational resolution; and
generating a drive signal by comparing the reference signal and the feedback signal, to drive the motor at a phase and speed of rotation determined by the frequency and phase of the reference signal, so that the phase of rotation of the motor is
locked to the phase of the reference signal, immediately after the motor speed reaches the reference speed value, such that deviation of the phase of rotation relative to the phase of the reference signal at steady state is substantially smaller than the
rotational resolution of the sensing device,
wherein comparing the reference signal and the feedback signal comprises generating a phase-frequency signal responsive to the deviation between the phase of the reference and the phase of rotation of the motor, and wherein the phase-frequency
signal is processed to generate the drive signal, and
wherein generating the drive signal comprises integrating the
phase-frequency signal to generate a modified phase-frequency signal, responsive to the phase-frequency signal and the feedback signal, wherein the modified phase-frequency signal is characterized by a second-order astatism.
22. A method according to claim 21, wherein integrating the phase-frequency signal comprises comparing a phase of the phase-frequency signal to the phase of the feedback signal.
23. A method according to claim 21, wherein generating the reference and phase-frequency signals comprises generating the signals responsive to a first clock input, and wherein generating the modified signal comprises generating the signal
responsive to a second clock input, asynchronous with the first clock input.
24. A method for controlling an electric motor, comprising:
generating a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit;
receiving a feedback signal from a rotation detector coupled to the motor, the detector having an inherent angular rotational resolution; and
generating a drive signal by comparing the reference signal and the feedback signal, to drive the motor at a phase and speed of rotation determined by the frequency and phase of the reference signal, so that the phase of rotation of the motor is
locked to the phase of the reference signal, immediately after the motor speed reaches the reference speed value, such that deviation of the phase of rotation relative to the phase of the reference signal at steady state is substantially smaller than the
rotational resolution of the sensing device,
wherein comparing the reference signal and the feedback signal comprises generating a phase-frequency signal responsive to the deviation between the phase of the reference and the phase of rotation of the motor, and wherein the phase-frequency
signal is processed to generate the drive signal, and
wherein generating the drive signal comprises integrating the phase-frequency signal to generate a modified phase-frequency signal, responsive to the phase-frequency signal and the feedback signal, wherein the modified phase-frequency signal is
characterized by a second-order astatism, and integrating the modified signal to produce a further modified signal having a third- or higher-order astatism.
25. A method, for controlling an electric motor, comprising:
generating a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit;
receiving a feedback signal from a rotation detector coupled to the motor, the detector having a predetermined rotational resolution; and
generating a drive signal by comparing the reference signal and the feedback signal, to drive the motor at a phase and speed of rotation determined by the frequency and phase of the reference signal, so that the phase of rotation of the motor is
locked to the phase of the reference signal, such that when the frequency of the reference signal is changed to a new frequency thereof, the rotation of the motor changes to a new speed, determined by the new frequency, substantially without overshoot or
undershoot,
wherein receiving the feedback signal comprises receiving a periodic signal having a frequency and phase dependent on the rotation of the motor, and wherein comparing the reference signal and the feedback signal comprises generating a
phase-frequency signal responsive to a phase deviation between the phase of the reference and feedback signals, and
wherein generating the phase-frequency signal comprises controlling a phase of the signal automatically responsive to a change in the motion parameters, so as to prevent the overshoot or undershoot, and
wherein controlling the phase comprises controlling transitions among a plurality of states in an edge-controlled memory network.
26. A method for controlling an electric motor, comprising:
generating a reference signal having a phase and frequency determined in accordance with a set of motion parameters input to the circuit;
receiving a feedback signal from a rotation detector coupled to the motor, the detector having a predetermined rotational resolution; and
generating a drive signal by comparing the reference signal and the feedback signal, to drive the motor at a phase and speed of rotation determined by the frequency and phase of the reference signal, so that the phase of rotation of the motor is
locked to the phase of the reference signal, such that the drive signal comprises a series of pulses having a pulse repetition frequency substantially higher than the frequency of the feedback signal,
wherein generating the drive signal comprises generating a series of pulse bursts, wherein the number of pulses in each burst is generally dependent on the phase deviation between the phase of the reference signal and the phase of rotation of the
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Claims |
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Description |
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FIELD OF THE INVENTION
The present invention relates generally to electric motor control and specifically to methods and apparatus for phase, speed and position control of electric motors.
BACKGROUND OF THE INVENTION
Accurate motion control is necessary in many applications involving electric motors. Typically, the control is needed over one or more of the motion parameters, i.e., speed, location and phase, with varying degrees of precision. Such control is
generally achieved by automatic control systems, for example, phase-locked speed controllers.
FIG. 1 is a schematic illustration of a phase-locked speed controller system 18, as is known in the art. A rotation detector 22 detects the rotational speed .OMEGA..sub.E of a motor 20 and generates an output pulse train having a frequency
f.sub.E and a phase .PHI..sub.E, in response thereto. External speed and phase reference values and a clock signal of a frequency f.sub.clock, generated by a clock generator 28, are input to a programmable reference 25, which generates a reference pulse
train of a frequency f.sub.R and a phase .PHI..sub.R. A correction device 24 receives the feedback and reference pulse trains and generates a feedback pulse train of a frequency fE and a phase .PHI..sub.F. A phase-frequency comparator 30, comprising,
for example, an edge-controlled digital memory network, as is known in the art, compares the frequency and phase of the feedback pulse train to those of the reference pulse train, and generates a duty cycle-modulated signal of having a duty cycle
.gamma..sub.1 in response to the difference between the two sets of values. The duty cycle signal is input to an integrator 32 to further generate a low-frequency pulse width-modulated (PWM) signal. This signal is output to a motor drive 36, which
drives motor 20 in response thereto.
Control systems like system 18 typically exhibit large and irregular overshoot, i.e., slow convergence of speed transients. These problems are mainly due to low-frequency reference and feedback signals, whose frequencies can be varied only in
discrete steps, as well as low-frequency PWM driving signals and slow response time of the phase control system. The system is typically subject to phase errors due to a "dead zone" effect in the integration circuit at low duty cycle pulse widths.
There is no accurate and reliable way of controlling motor speeds in the range below a few tens of rpm, employing the above-described control systems. Similarly, there is no straightforward way for systems like system 18 to control with any accuracy the
shaft position of the motor.
Attempts at improving one or more of the controlling parameters of phase-locked control systems have been performed mostly in relation to specific, dedicated applications, such as in video and digital audio recorders and players, where rapid
response, i.e., rapid phase convergence during speed transients, is mandatory.
For example, U.S. Pat. No. 4,795,950, to Ota, et al., which is incorporated herein by reference, describes methods and apparatus for phase control of video and audio digital recorder motors with rapid phase convergence using a resettable phase
signal generating circuit for producing a reference phase signal. The signal generating circuit is reset in response to a speed signal when the speed is in a prescribed range, thus controlling the phase convergence time in response to changes in the
speed, i.e., during speed transients.
At present, users of control systems have a choice between microprocessor-based and pulse logic control techniques. The availability of high-power microprocessors makes them suitable for many applications. Nevertheless, the simplicity, low cost
and inherent high precision of pulse logic methods make them a preferred choice whenever applicable.
SUMMARY OF THE INVENTION
It is an object of some aspects of the present invention to provide a reliable and accurate method and apparatus for automatic speed, phase and/or position control of an electric motor.
It is a further object of some aspects of the present invention to provide a reliable and accurate apparatus and method for automatic control at low rotation speeds of an electric motor.
Methods and apparatus in accordance with preferred embodiments of the present invention use novel pulse logic processing techniques to achieve high-precision motion control functions. These techniques, as described hereinbelow, eliminate some of
the problems known to affect the accuracy and reliability of motion control systems known in the art.
In preferred embodiments of the present invention, a motion controller for an electric motor comprises a rotation detector, w | | |
