Absolute capacitive sensing using sensor electrode pre-emphasis

What is claimed is: 1. A processing system comprising: a sensor module configured to: drive a modulated signal on to a sensor electrode to achieve a target voltage on said sensor electrode during a first portion of a sensing cycle, wherein said modulated signal comprises: a first voltage that is beyond a level of said target voltage and which is driven for a first period of time, and a second voltage that is at said target voltage and which is driven for a second period of time that follows said first period of time, decouple said sensor electrode from an amplifier using a first switch, couple, while said sensor electrode is decoupled from said amplifier, said first voltage with said sensor electrode through a second switch during said first period of time, couple, while said sensor electrode is decoupled from said amplifier, said second voltage with said sensor electrode through a third switch during said second period of time, couple said sensor electrode with said amplifier using said first switch while said first voltage is decoupled from said sensor electrode using said second switch and while said second voltage is decoupled from said sensor electrode using said third switch; and a determination module configured to determine an absolute capacitance of said sensor electrode during said first portion of said sensing cycle only after said second voltage is coupled with said sensor electrode, said second voltage is driven, and said sensor electrode is caused, by said second voltage, to settle at said target voltage. 2. The processing system of claim 1 , wherein said sensor module is further configured to drive said modulated signal on to said sensor electrode to achieve a second target voltage on said sensor electrode during a second portion of said sensing cycle, wherein said target voltage and said second target voltage are different voltages, wherein said second portion follows said first portion, and wherein said modulated signal comprises a third voltage that is beyond a level of said second target voltage and which is driven for a third period of time and a fourth voltage that is at said second target voltage and which is driven for a fourth period of time that follows said third period of time; and wherein said determination module is further configured to further determine said absolute capacitance of said sensor electrode during said second portion of said sensing cycle only after said fourth voltage is driven and said sensor electrode is caused, by said fourth voltage, to settle at said second target voltage. 3. The processing system of claim 2 , wherein said sensor module is configured to: couple said third voltage with said sensor electrode through a fourth switch during said third period of time; and couple said fourth voltage with said sensor electrode through a fifth switch during said fourth period of time, wherein said determination module is configured to determine said absolute capacitance during said second portion of said sensing cycle only after said fourth voltage has been coupled with said sensor electrode and said fourth voltage has caused said sensor electrode to settle at said second target voltage. 4. The processing system of claim 2 , wherein said sensor module is configured to adjust a length of at least one of said third period of time and fourth period of time. 5. The processing system of claim 1 , wherein said sensor module is configured to drive said modulated signal by driving a reference input of a receiver coupled with said sensor electrode. 6. The processing system of claim 1 , wherein said sensor module is configured to adjust a length of at least one of said first period of time and second period of time. 7. The processing system of claim 1 , wherein said sensor module comprises a receiver coupled with said sensor electrode, the receiver having a reference input, where said sensor module is configured to: drive said reference input to effect a charge offset while receiving resulting signals with the receiver. 8. A capacitive sensing input device, said capacitive sensing input device comprising: a plurality of sensor electrodes; and a processing system configured to operate said sensor electrodes to perform absolute capacitive sensing, wherein said processing system configured to: drive a modulated signal on to a sensor electrode of said plurality of sensor electrodes to achieve a target voltage on said sensor electrode during a first portion of a sensing cycle, wherein said modulated signal comprises: a first voltage that is beyond a level of said target voltage and which is driven for a first period of time, and a second voltage that is at said target voltage and which is driven for a second period of time that follows said first period of time; decouple said sensor electrode from an amplifier using a first switch, couple, while said, sensor electrode is decoupled from said amplifier, said first voltage with said sensor electrode through a second switch during said first period of time, couple, while said sensor electrode is decoupled from said amplifier, said second voltage with said sensor electrode through a third switch during said second period of time, couple said sensor electrode with said amplifier using said first switch while said first voltage is decoupled from said sensor electrode using said second switch and while said second voltage is decoupled from said sensor electrode using said third switch, determine an absolute capacitance of said sensor electrode during said first portion of said sensing cycle only after said second voltage is coupled with said sensor electrode, driving said second voltage and causing, by said second voltage, said sensor electrode to settle at said target voltage; drive said modulated signal on to said sensor electrode to achieve a second target voltage on said sensor electrode during a second portion of said sensing cycle, wherein said target voltage and said second target voltage are different voltages, wherein said second portion follows said first portion, and wherein said modulated signal comprises a third voltage and a fourth voltage, said third voltage beyond a level of said second target voltage and driven for a third period of time, said fourth voltage at said second target voltage and driven for a fourth period of time that follows said third period of time; and further determine said absolute capacitance during said second portion of said sensing cycle only after driving said fourth voltage and causing, by said fourth voltage, said sensor electrode to settle at said second target voltage. 9. The capacitive sensing input device of claim 8 , wherein said processing system is further configured to: drive said modulated signal by driving a reference input of a receiver coupled with said sensor electrode. 10. The capacitive sensing input device of claim 8 , wherein said processing system is further configured to: couple said third voltage with said sensor electrode through a fourth switch during said third period of time; and couple said fourth voltage with said sensor electrode through a fifth switch during said fourth period of time, wherein said processing system is configured to determine said absolute capacitance of said sensor electrode during said second portion of said sensing cycle only after said fourth voltage has been coupled with said sensor electrode and said fourth voltage has caused said sensor electrode to settle at said second target voltage. 11. The capacitive sensing input device of claim 10 , wherein said processing system is further configured to: drive a reference input of a receiver to effect a first charge offset while determining said absolute capac