Claims
- 1. A DC--DC converter comprising:
- an input node receiving an input voltage V.sub.IN ;
- a pulse width modulation (PWM) unit coupled to chop said input voltage V.sub.IN into a square wave under control of a V.sub.DRIVE signal;
- an output stage converting the chopped input voltage V.sub.IN to an output voltage V.sub.OUT coupled to an output node;
- a reference voltage generator providing a voltage V.sub.REF ;
- a hysteresis voltage generator providing a voltage V.sub.HYST ;
- a first comparator generating a signal determined from a difference between said voltage V.sub.REF and said output voltage V.sub.OUT ;
- a second comparator generating a signal determined from a difference between said output voltage V.sub.OUT and said voltage V.sub.HYST ;
- a latch coupled to receive the outputs of the first and second comparator, the latch generating an output; and
- a driver circuit coupled to receive the latch output and generate the V.sub.DRIVE signal.
- 2. The DC--DC converter of claim 1 wherein the output stage comprises a buck regulator stage.
- 3. The DC--DC converter of claim 1 wherein the output stage comprises a synchronous buck regulator stage.
- 4. The DC--DC converter of claim 1 wherein the hysteresis voltage generator further comprises:
- a resistor ladder having a plurality of taps;
- a voltage source coupled across the resistor ladder;
- a summing node;
- a switch coupled between the summing node and each tap; and
- a control device coupled to each switch to selectively activate the switch so as to programmably couple each node to the summing node, wherein said voltage V.sub.HYST is a voltage on the summing node.
- 5. The DC--DC converter of claim 4 further comprising:
- a first OR gate coupled between the first comparator output and the latch, the first OR gate comprising a first input coupled to the output of the first comparator, a second input coupled to receive a first masking signal, and an output coupled to the latch; and
- a rising edge delay unit coupled to the latch output to feedback the latch output to provide the first masking signal to the second input of the first OR gate.
- 6. The DC--DC converter of claim 5 further comprising:
- a second OR gate coupled between the second comparator output and the latch, the second OR gate comprising a first input coupled to the output of the second comparator, a second input coupled to receive a second masking signal, and an output coupled to the latch;
- an inverter coupled to the latch output and provide an inverted latch output signal; and
- a rising edge delay unit coupled to the inverted latch output signal to feedback the inverted latch output to provide the second masking signal to the second input of the second OR gate.
- 7. The DC--DC converter of claim 1 wherein the latch comprises an SR latch having a set input and a reset input.
- 8. The DC--DC converter of claim 7 wherein the first comparator further comprises:
- a non-inverting input coupled to said voltage V.sub.REF ;
- an inverting input coupled to said output voltage V.sub.OUT ; and
- an output coupled to the reset input of the SR latch.
- 9. The DC--DC converter of claim 7 wherein the second comparator further comprises:
- a non-inverting input coupled to said output voltage V.sub.out ;
- an inverting input coupled to said voltage V.sub.HYST ; and
- an output coupled to the set input of the SR latch.
- 10. A hysteretic comparator for comparing a sample voltage comprising:
- a reference voltage generator providing a voltage V.sub.REF ;
- a hysteresis voltage generator providing a voltage V.sub.HYST ;
- a first comparator generating a signal determined from a difference between said voltage V.sub.REF and a voltage V.sub.OUT ;
- a second comparator generating a signal determined from a difference between said voltage V.sub.OUT and said voltage V.sub.HYST ;
- a latch having a reset input coupled to the output of the first comparator and a set input coupled to the output of the second comparator, the latch generating an output signal on an output node (Q);
- a driver circuit coupled to receive the latch output and generate a V.sub.DRIVE signal; and
- a pulse suppression unit responsive to the latch output signal to disable the reset input in a first operating mode.
- 11. The hysteretic comparator of claim 10 wherein the hysteresis voltage generator derives said voltage V.sub.HYST from a resistor ladder coupled to said voltage V.sub.REF.
- 12. The hysteretic comparator of claim 10 further comprising:
- an inverter coupled to the latch output signal and generating an inverted latch output signal; and
- a second pulse suppression unit responsive to the inverted latch output signal to disable the set input in a second operating mode.
- 13. The hysteretic comparator of claim 12 wherein the first and second pulse suppression units comprise rising-edge delay circuits.
- 14. The hysteretic comparator of claim 10 wherein the first comparator further comprises:
- a non-inverting input coupled to said voltage V.sub.REF ;
- an inverting input coupled to said voltage V.sub.OUT ; and
- an output coupled to the reset input of the latch.
- 15. The hysteretic comparator of claim 10 wherein the second comparator further comprises:
- a non-inverting input coupled to said voltage V.sub.OUT ;
- an inverting input coupled to said voltage V.sub.HYST ; and
- an output coupled to the set input of the latch.
- 16. The hysteretic comparator of claim 10 further comprising:
- a first OR gate coupled between the first comparator output and the reset input of the latch, the first OR gate comprising an input coupled to the pulse suppression unit, and an output coupled to the reset input of the latch; and
- a rising edge delay unit within the pulse suppression unit and coupled to the latch output to feedback the latch output to provide the first masking signal to the second input of the first OR gate.
- 17. A method of generating a pulse width modulated signal for driving an output stage of a regulator, the regulator including an input stage receiving an input voltage V.sub.IN and an output stage providing an output voltage V.sub.OUT, the method comprising the steps of:
- generating a reference voltage V.sub.REF ;
- generating a hysteresis voltage V.sub.HYST ;
- comparing said reference voltage V.sub.REF to said output voltage V.sub.OUT to determine a first binary difference signal;
- comparing said output voltage V.sub.OUT to said hysteresis voltage V.sub.HYST to determine a second binary difference signal;
- setting a latch in response to the second binary difference signal;
- resetting the latch in response to the first binary difference signal;
- generating the pulse width modulated signal by amplifying a latch output signal;
- chopping the input voltage V.sub.IN into a square wave using the pulse width modulated signal; and
- converting the square wave into said output voltage V.sub.OUT using a low pass filter.
- 18. The method of claim 17 further comprising:
- in a first mode, disabling the latch from setting for a preselected time after a rising edge occurs on the latch output signal; and
- in a second mode, disabling the latch from resetting for the preselected time after a falling edge occurs on the latch output signal.
Parent Case Info
This application claims priority under 35 USC .sctn. 119(e)(1) of provisional application Ser, No. 60/068,546 filed Dec. 23, 1997.
US Referenced Citations (6)