An apparatus and method for controlling a device using pulse signals. In the apparatus and method, a two-stage control is used to generate pulse signals, which can be a PWM signal, a pulse signal including a PWM signal with a sleeping time, or a PDM signal. The two-stage control includes a second st
An apparatus and method for controlling a device using pulse signals. In the apparatus and method, a two-stage control is used to generate pulse signals, which can be a PWM signal, a pulse signal including a PWM signal with a sleeping time, or a PDM signal. The two-stage control includes a second stage control, which generates pulse signals according to parameter values generated periodically by a first stage according to a target value and feedback sensing values. The two-stage control can be used in decreasing perturbation in a closed-loop control and accurate open-loop control.
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1. A control apparatus for energizing and de-energizing a device to control an output value of said device according to a predetermined target value, comprising: a switching means controlling an energizing time and a de-energizing time of said device;at least one parameter sensor for providing param
1. A control apparatus for energizing and de-energizing a device to control an output value of said device according to a predetermined target value, comprising: a switching means controlling an energizing time and a de-energizing time of said device;at least one parameter sensor for providing parameter sensing values indicative to changes in parameters of a transfer function between a ratio of said energizing time to said de-energizing time and said output value; anda pulse signal controller for providing a PWM control signal to said switching means, including a first stage controller providing values of control parameters for a second stage controller according to at least said predetermined target value and said parameter sensing values obtained from said at least one parameter sensor, wherein said second stage controller is further configured to generate a second stage PWM signal, and said first stage controller is further configured to generate a first stage PWM control signal by periodically providing values of control parameters for said second stage controller, and at least two cycles of said second stage PWM signal are generated in one cycle of said first stage PWM signal. 2. The control apparatus of claim 1, wherein in each cycle of said first stage PWM signal, in all cycles of said second stage PWM signal with non-zero on-time, at least one cycle has its control parameters determined in a different way from other cycles. 3. The control apparatus of claim 2, wherein said at least one cycle of said second stage PWM signal is after said other cycles of said second stage PWM signal. 4. The control apparatus of claim 1, wherein said pulse signal controller is configured to report a fault if in a predetermined number of cycles of said first stage PWM signal, all cycles of said second stage PWM signal with non-zero on-time are determined in the same way. 5. The control apparatus of claim 1, wherein said device is a power supply, and said parameters of said transfer function include a voltage of said power supply. 6. The control apparatus of claim 1, wherein said device is a common rail flow control device including a rail with a working fluid contained inside, and said parameters of said transfer function include a pressure of said working fluid in said rail of said common rail flow control device. 7. The control apparatus of claim 1, further comprising: at least one output sensor providing output sensing values indicative to said output value of said device, wherein said first stage controller is further configured to provide values of control parameters for said second stage PWM signal according to at least said output sensing values obtained from said output sensor. 8. A control apparatus for energizing and de-energizing a device to control an output value of said device according to a predetermined target value, comprising: a switching means controlling an energizing time and a de-energizing time of said device;at least one parameter sensor for providing parameter sensing values indicative to changes in parameters of a transfer function between a ratio of said energizing time to said de-energizing time and said output value; anda pulse signal controller for providing a pulse control signal to said switching means, including a first stage controller providing values of control parameters for a second stage controller according to at least said predetermined target value and said parameter sensing values obtained from said at least one parameter sensor, wherein said second stage controller is further configured to generate a second stage pulse signal, each pulse in which includes a sleep time section, an on-time section, and an off-time section, and said first stage controller is further configured to generate a first stage pulse signal, each cycle of which includes at least two second stage pulses, by setting values of said control parameters for said second stage controller in each cycle of said second stage pulse signal. 9. The control apparatus of claim 8, wherein in each cycle of said first stage pulse signal, in all cycles of said second stage pulse sequence signal with non-zero on-time, at least one cycle has its control parameters determined in a different way from other cycles. 10. The control apparatus of claim 8, wherein in each cycle of said first stage pulse signal, in all cycles of said second stage pulse signal, at least one cycle has its sleep time determined in a different way from other cycles. 11. The control apparatus of claim 8, wherein said device is a power supply, and said parameters of said transfer function include a voltage of said power supply. 12. The control apparatus of claim 8, wherein said device is a common rail flow control device including a rail with a working fluid contained inside, and said parameters of said transfer function include a pressure of said working fluid in said rail of said common rail flow control device. 13. The control apparatus of claim 8, wherein said pulse signal generator is configured to report a fault if in a predetermined number of cycles of said first stage pulse signal, all cycles of said second stage pulse signal with non-zero on-time are determined in the same way. 14. The control apparatus of claim 8, wherein said first stage pulse signal is a pulse duration modulated signal. 15. The control apparatus of claim 14, wherein in each cycle of said first stage pulse signal, in all cycles of said second stage pulse signal, at least one cycle has its sleep time determined in a different way from other cycles. 16. The control apparatus of claim 14, wherein said pulse signal controller is configured to report a fault if said sleep time of said second stage pulse signal is calculated longer than a predetermined threshold value. 17. A method for controlling an apparatus including a control device, a switching means controlling an energizing time and a de-energizing time of said control device, a pulse signal controller for generating a pulse signal to said switching means, and at least one sensor, comprising steps of: (a) calculating a current control value using sensing values obtained from said at least one sensor;(b) calculating an error by subtracting said current control value from a predetermined target value;(c) updating parameters of said pulse signal controller in each cycle of said pulse signal by setting said parameters to a first set of values in a cycle of said pulse signal when said error is greater than a predetermined value, and setting said parameters to a second set of values in a cycle of said pulse signal and setting said parameters to a third set of values in a following cycle otherwise;(d) generating a fault signal when said second set of values are not set in a predetermined period of time;(e) initializing said current control value after setting parameters to said third set of values; and(f) repeating steps (a) to (e). 18. The method of claim 17, wherein said pulse signal controller generates a PWM signal, and said parameters of said pulse signal controller determine a duty cycle of said PWM signal. 19. The method of claim 17, wherein said pulse signal controller generates a PWM signal with a sleep-time section, and said parameters of said pulse signal controller determine a duration time of said sleep section and a duty cycle of said PWM signal.
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