Ratio-metric self-capacitance-to-code convertor

What is claimed is: 1. A capacitance-to-code converter comprising: a first charge transfer circuit comprising a sensor capacitor alternately coupled to first voltage potential and a first integration capacitor through a first deadband switch network; a second charge transfer circuit comprising a modulation capacitor alternately coupled to second voltage potential and a second integration capacitor through a second deadband switch network; a comparator circuit coupled to the first charge transfer circuit at the first integration capacitor and the second charge transfer circuit at the second integration capacitor, the comparator configured to output a bitstream; and a digitizer configured to convert the bitstream to a digital value representative of the a capacitance of the sensor capacitor. 2. The capacitance-to-code converter of claim 1 , wherein a clock source of the second charge transfer circuit is derived from the bitstream output of the comparator and a system clock. 3. The capacitance-to-code converter of claim 1 , wherein the digitizer comprises a digital filter configured to reduce a sample rate on an input of the digitizer. 4. The capacitance-to-code converter of claim 1 , wherein the first and second charge transfer circuits comprise a first and second reset switch, respectively, the first and second reset switches configured to discharge the first and second integration capacitors, respectively. 5. The capacitance-to-code converter of claim 1 , wherein the first charge transfer circuit is clocked by a system clock. 6. The capacitance-to-code converter of claim 1 , wherein the modulation capacitor, in a first mode, comprises a sensor capacitor measurable by the capacitance-to-code converter and, in a second mode, comprises the sensor capacitor configured as the modulation capacitor. 7. The capacitance-to-code converter of claim 1 , wherein at least one of the first and second integration capacitor is disposed on an integrated circuit comprising the capacitance-to-code converter. 8. The capacitance-to-code converter of claim 1 , wherein at least one of the first and second integration capacitor is disposed external to an integrated circuit comprising the capacitance-to-code converter. 9. The capacitance-to-code converter of claim 1 , wherein the digitizer comprises a decimator coupled to the output of comparator, the decimator configured to count a number of clock cycles from a system clock. 10. A system comprising: at least one electrode comprising a capacitance that alterable by the proximity of a conductive object to the electrode; and a capacitance measurement circuit comprising: a first charge transfer circuit coupled to the at least one electrode and a first integration capacitor, the first charge transfer circuit comprising a first deadband switch network for alternately coupling the at least one electrode to a first voltage potential and the first integration capacitor; a second charge transfer circuit comprising a modulation capacitor and a second integration capacitor, the second charge transfer circuit comprising a second deadband switch network for alternately coupling the modulation capacitor to a second voltage potential and the second integration capacitor; a comparator comprising a first input coupled to the first charge transfer circuit at the first integration capacitor and a second input coupled to the second charge transfer circuit at the second integration capacitor, the comparator configured to output a bitstream; and a digitizer configured to convert the bitstream to a digital value representative of the a capacitance of the sensor capacitor. 11. The system of claim 10 , wherein the at least one electrode comprises: a first electrode configured to comprise a capacitance that may vary in response to the proximity of a conductive object to the first electrode; and a second electrode comprising a capacitance that does not vary in response to the proximity of a conductive object to the first electrode. 12. The system of claim 11 , wherein the second electrode is the modulation capacitor of the second charge transfer circuit in a first mode and is the sensor capacitor of the first integration circuit in a second mode. 13. The system of claim 10 , wherein a clock source of the second charge transfer circuit is derived from the bitstream output of the comparator and a system clock. 14. The system of claim 10 , wherein the first and second charge transfer circuits comprise a first and second reset switch, respectively, the first and second reset switches configured to discharge the first and second integration capacitors, respectively. 15. The system of claim 10 , wherein at least one of the first and second integration capacitor is disposed external to an integrated circuit comprising the capacitance-to-code converter. 16. A method of measuring capacitance comprising accumulating charge on a first integration capacitor through a plurality of first charge transfer operations using a first deadband switch network; accumulating charge on a second integration capacitor through a plurality of second charge transfer operations using a second deadband switch network; generating a bitstream from a comparison of the first and second accumulated charges; and converting the bitstream to a digital value representative of a sensor capacitance, the sensor capacitance used in the first charge transfer operation. 17. The method of claim 16 , wherein the plurality of first charge transfer operations comprises: accumulating charge on the sensor capacitance in a first phase; and transferring the charge from the sensor capacitance to an integration capacitor in a second phase. 18. The method of claim 16 , wherein the second charge transfer operation includes: accumulating charge on a modulation capacitance in a first phase; and transferring the charge from the modulation capacitance to an integration capacitor in a second phase. 19. The method of claim 16 , wherein the first and second charge transfer operations include a reset operation.