Low cost highly manufacturable DC-to-DC power converter
First Claim
1. A control circuit for use in a power converter, the power converter having a switch for alternately energizing and de-energizing a primary winding of a transformer, wherein the switch has a gate input for receiving a gate control signal, and the power converter produces a regulated voltage output signal, the control circuit comprising:
- a feedback circuit coupled to the regulated voltage output signal, the feedback circuit producing a feedback control signal based on a comparison between a compare signal derived from the regulated voltage output signal and a reference signal;
a control window circuit coupled to the feedback control signal, wherein the control window circuit produces an upper control signal and a lower control signal from the feedback control signal;
a first resistive network coupled to a first energy storage device, wherein a charge time of the first energy storage device is equal to a time interval required to change an electrical state of the first energy storage device from that of the lower control signal to that of the upper control signal such that the charge time varies with the feedback signal;
a second resistive network coupled to a second energy storage device, wherein a discharge time of the second energy storage device is equal to a time interval required to discharge an electrical state of the second storage device from that of the upper control signal to that of the lower control signal such that the discharge time varies with the feedback signal; and
a switching circuit coupled to the upper and lower control signals and the first and second resistive networks, for alternately charging the first energy storage device through the first resistive network and discharging the second energy storage device through the second resistive network, and forming the gate control signal, wherein the gate control signal assumes a first state based on the charge time and a second state based on the discharge time.
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Accused Products
Abstract
A highly manufacturable low cost DC-to-DC power converter uses a control circuit constructed from a '"'"'555 type timer IC and a precision voltage reference. The output of the '"'"'555 timer is used to drive a MOSFET transistor that alternately energizes and de-energizes a primary winding of a transformer, thereby energizing secondary windings of the transformer. The voltage at the secondary windings is rectified and filtered to form the regulated output supply voltages. A feedback control signal is generated based on a difference between a reference voltage and the a regulated output supply voltage. Based on the feedback control signal, a control window is established within the '"'"'555 timer that determines the charging and discharging times of a capacitor. Since the charging and discharging times of the capacitor are exponential, changing the feedback control signal changes the control window, which in turn changes the charging time with respect to the discharging time. While the times change with respect to each other, the sum of the charging time and the discharging time remains relatively constant, so the oscillation frequency remains relatively constant. Accordingly, the present invention achieves pulse width modulation (PWM) type control at a cost much lower than the cost of commercially available controller ICs.
188 Citations
16 Claims
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1. A control circuit for use in a power converter, the power converter having a switch for alternately energizing and de-energizing a primary winding of a transformer, wherein the switch has a gate input for receiving a gate control signal, and the power converter produces a regulated voltage output signal, the control circuit comprising:
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a feedback circuit coupled to the regulated voltage output signal, the feedback circuit producing a feedback control signal based on a comparison between a compare signal derived from the regulated voltage output signal and a reference signal; a control window circuit coupled to the feedback control signal, wherein the control window circuit produces an upper control signal and a lower control signal from the feedback control signal; a first resistive network coupled to a first energy storage device, wherein a charge time of the first energy storage device is equal to a time interval required to change an electrical state of the first energy storage device from that of the lower control signal to that of the upper control signal such that the charge time varies with the feedback signal; a second resistive network coupled to a second energy storage device, wherein a discharge time of the second energy storage device is equal to a time interval required to discharge an electrical state of the second storage device from that of the upper control signal to that of the lower control signal such that the discharge time varies with the feedback signal; and a switching circuit coupled to the upper and lower control signals and the first and second resistive networks, for alternately charging the first energy storage device through the first resistive network and discharging the second energy storage device through the second resistive network, and forming the gate control signal, wherein the gate control signal assumes a first state based on the charge time and a second state based on the discharge time. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A control circuit for use in a power converter, the power converter having a switch for alternately energizing and de-energizing a primary winding of a transformer, wherein the switch has a gate input for receiving a gate control signal, and the power converter produces a regulated voltage output signal, the control circuit comprising:
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a timer circuit having a control input, a threshold input, a trigger input, and a timer output, wherein the control input establishes a control window bounded by an upper control value and a lower control value, the timer output assumes a first state based on a signal applied to the trigger input failing below the lower control value, the timer output assumes a second state based on a signal applied to the threshold input exceeding the upper control value, and the gate control signal is derived from the timer output; a feedback circuit coupled to the regulated voltage output signal, wherein the feedback circuit produces a feedback control signal that is coupled to the control input of the timer circuit, and the feedback control signal varies based on a comparison between a voltage of the regulated voltage signal and a reference voltage; a capacitor coupled to the threshold and trigger inputs of the timer circuit, to provide a signal based on a voltage across the capacitor to the threshold and trigger inputs; a first resistive network coupled to the capacitor, for charging the capacitor when the timer output assumes the first state; a second resistive network coupled to the capacitor, for discharging the capacitor when the timer output assumes the second state; and a switching network coupled to the first and second resistive networks and the timer output signal, for charging the capacitor for a charge time interval when the timer output assumes the first state and discharging the capacitor for a discharge time interval when the timer output assumes the second state, wherein the charge time interval and the discharge time interval each vary based on the feedback control signal. - View Dependent Claims (10, 11, 12)
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13. A method of controlling a power converter having a switch for alternately energizing and de-energizing a primary winding of a transformer, wherein the switch has a gate input for receiving a gate control signal, and the power converter produces a regulated voltage output signal, the method comprising:
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forming a feedback signal by comparing a compare signal based on the regulated voltage output signal to a reference signal; forming an upper control signal and a lower control signal from the feedback signal; charging a first energy storage device from a state equal to the lower control signal to a state equal to the upper control signal, wherein a charge interval is equal to a length of time required to charge the first energy storage device from the state equal to the lower control signal to the state equal to the upper control signal and varies based on the feedback signal; discharging a first energy storage device from the state equal to the upper control signal to the state equal to the lower control signal, wherein a discharge interval is equal to a length of time required to discharge the first energy storage device from the state equal to the upper control signal to the state equal to the lower control signal and varies based on the feedback signal; and forming the gate control signal based upon the charge interval and the discharge interval. - View Dependent Claims (14)
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15. A power converter comprising:
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a transformer comprising; a primary winding; and a secondary winding; a switch for alternately energizing and de-energizing the primary winding, wherein the switch has a gate input for receiving a gate control signal an output rectifier and filter circuit coupled to the secondary winding and providing a regulated voltage output signal; a timer circuit having a control input, a threshold input, a trigger input, a discharge terminal, and a timer output, wherein the control input establishes a control window bounded by an upper control value and a lower control value, the timer output assumes a first state based on a signal applied to the trigger input failing below the lower control value, the timer output assumes a second state based on a signal applied to the threshold input exceeding the upper control value, the discharge terminal is coupled to ground when the timer output assumes the second state, and the gate control signal is derived from the timer output; a feedback circuit coupled to the regulated voltage output signal, wherein the feedback circuit produces a feedback control signal that is coupled to the control input of the timer circuit, and the feedback control signal varies based on a comparison between a voltage of the regulated voltage signal and a reference voltage; a capacitor coupled to the threshold and trigger inputs of the timer circuit, to provide a signal based on a voltage across the capacitor to the threshold and trigger inputs; and a resistive network coupled to the capacitor and the discharge terminal, for charging the capacitor when the timer output assumes the first state and discharging the capacitor when the timer output assumes the second state, wherein a charge time during which the capacitor charges and a discharge time during which the capacitor discharges each vary with the feedback control signal. - View Dependent Claims (16)
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Specification