Method and apparatus for offset calibration of a multi-mode high-speed comparator

What is claimed is: 1. A calibration circuit comprising: a mode module to select operation in a first mode or a second mode; a bias module to generate (i) a first bias current for a preamplifier of a comparator while in the first mode, and (ii) a second bias current for the preamplifier while in the second mode; a calibration module to, during calibration of the first mode, (i) connect inputs of the preamplifier together to receive a predetermined voltage; an offset module to (i) determine an offset based on (a) output voltages of the preamplifier, or (b) an output voltage of the comparator, and (ii) generate a control signal based on whether the offset is within a first predetermined range; a resistance module to, based on the control signal and during calibration of the first mode, adjust a first resistance of a resistor in a resistance set of the preamplifier for the first mode; and a code module to generate a calibration code based on the first resistance, wherein the resistance module is to, subsequent to calibrating the first mode, calculate a second resistance set for second mode based on the calibration code determined during the calibration of the first mode. 2. The calibration circuit of claim 1 , wherein: the offset module is to: generate the control signal to adjust the first resistance, monitor the output voltage of the comparator while the first resistance is being adjusted, and when a digital state or a polarity of the output voltage changes, generate the control signal to cease adjustment of the first resistance; the first resistance is a calibrated resistance for the first mode when the digital state or polarity of the output voltage changes; and the code module is to generate the calibration code to include the calibrated resistance. 3. The calibration circuit of claim 1 , wherein: the offset is a first offset; and the offset module is to: monitor two or more of (i) the output voltages of the preamplifier, and (ii) the output voltage of the comparator; determine a plurality of offsets based respectively on (i) the output voltages of the preamplifier, and (ii) the output voltages of the comparator, wherein the plurality of offsets include the first offset; and generate the control signal based on the plurality of offsets. 4. The calibration circuit of claim 1 , wherein: the code module is to generate the calibration code to include for the first mode the first resistance, the first bias current and a first gain of the preamplifier; and the resistance module is to calibrate the first mode based on (i) the first resistance, (ii) the first bias current, and (iii) the first gain of the preamplifier for the first mode. 5. The calibration circuit of claim 4 , wherein: the resistance module is to calculate the second resistance set based on (i) the second bias current, (ii) a second gain of the preamplifier for the second mode; and (iii) the first resistance set, and the resistance module is to determine a second resistance of the resistor based on the calibration code. 6. The calibration circuit of claim 1 , wherein the offset module is to: determine a total offset of the calibration circuit for the first mode based on (i) an offset for the preamplifier, and (ii) an offset for the comparator; and based on the total offset, generate the control signal to adjust the first resistance. 7. The calibration circuit of claim 6 , wherein the code module is to generate the calibration code if the total offset is within a second predetermined range. 8. The calibration circuit of claim 6 , wherein: the offset module is to determine a total offset of the calibration circuit for the first mode; and based on the total offset determined for the first mode, generate the control signal to adjust the first resistance; and the code module is to generate the calibration code if the total offset is within a predetermined range. 9. A comparator module comprising: the calibration circuit of claim 1 ; the preamplifier comprising (i) two input differential pair transistors, and (ii) two resistors connected in series respectively with the two input differential pair transistors; and the comparator. 10. A power converter comprising: the comparator module of claim 9 ; a power stage comprising a power transistor, a diode, an inductor, and an output capacitor; an output voltage sense circuit to receive an output voltage from the output capacitor; an error amplifier to (i) receive the output voltage, and (ii) generate a first input voltage for the comparator module; and a sensing circuit to (i) detect an amount of current passing through the inductor, and (ii) based on the amount of current passing through the inductor, generate a second input voltage for the comparator module, wherein the comparator is to (i) compare the first input voltage to the second input voltage, and (ii) based on the comparison, control a state of the transistor to adjust the amount of current passing through the inductor. 11. A calibration circuit comprising: a mode module to select operation in a first mode or a second mode; a bias module to generate (i) a first bias current for a preamplifier of a comparator while in the first mode, and (ii) a second bias current for the preamplifier while in the second mode; an offset module to, during calibration of the first mode, monitor an output voltage of the comparator, and (ii) generate a control signal based on the output voltage; a resistance module to, based on the control signal and during calibration of the first mode, adjust a first resistance of a resistor of the preamplifier for the first mode; and a code module to generate a calibration code based on the first resistance, wherein the resistance module is to, subsequent to calibrating the first mode, calibrate the second mode based on the calibration code in the first mode. 12. The calibration circuit of claim 11 , wherein: the offset module is to: generate the control signal to adjust the first resistance, monitor the output voltage of the comparator while the first resistance is being adjusted, and when a digital state or a polarity of the output voltage changes, generate the control signal to cease adjustment of the first resistance; the first resistance is a calibrated resistance for the first mode when the digital state or polarity of the output voltage changes; and the code module is to generate the calibration code to include the calibrated resistance. 13. The calibration circuit of claim 11 , wherein: the code module is to generate the calibration code to include for the first mode the first resistance, the first bias current and a first gain of the preamplifier; the resistance module is to calibrate the second mode based on the first resistance, the first bias current, the first gain of the preamplifier for the first mode, the second bias current, and a second gain of the preamplifier for the second mode; and the resistance module is to, while calibrating the second mode, determine a second resistance of the resistor based on the calibration code. 14. The calibration circuit of claim 11 , wherein the offset module is to: determine a total offset of the calibration circuit for the first mode based on (i) an offset for the preamplifier, and (ii) an offset for the comparator; and based on the total offset, generate the control signal to adjust the first resistance. 15. A method of calibrating a comparator circuit comprising: selecting operation in a first mode or a second mode; generating (i) a first bias current for a preamplifier of a comparator whi