Quasi-differential Mutual Capacitance Measurement

What is claimed is: 1 . A method comprising: in an initialization phase, charging a first integration capacitor and a second integration capacitor to a first voltage; in an integration phase, providing negative charge packets to the first integration capacitor and positive charge packets to the second integration capacitor, wherein the negative and positive charge packets are derived from a mutual capacitance and a transmit (TX) signal applied to the mutual capacitance; in a digitization phase: initiating a timer of a time measurement logic block, charging the first integration capacitor until the voltage across the first integration capacitor is substantially equal to the voltage across the second integration capacitor, and stopping the timer of the time measurement logic block, wherein the value of the timer is representative of the mutual capacitance; and providing the output of the digitization phase to a processing unit. 2 . The method of claim 1 , wherein the TX signal is applied to the mutual capacitance by: coupling a first electrode of the mutual capacitance to a first voltage in a first switching phase; coupling the first electrode of the mutual capacitance to a second voltage in a second switching phase. 3 . The method of claim 2 , wherein the positive charge packets are provided to the second integration capacitor when the first electrode of the mutual capacitance is coupled to the first voltage, the positive charge packets provided as a current received on a second electrode of the mutual capacitance. 4 . The method of claim 2 , wherein the negative charge packets are provided to the first integration capacitor when the first electrode of the mutual capacitance is coupled to the second voltage, the positive charge packets provided as a current received on a second electrode of the mutual capacitance. 5 . The method of claim 2 , wherein the first voltage is a power supply voltage and the second voltage is a ground potential. 6 . The method of claim 1 , wherein the charging of the first integration capacitor is by a current digital-to-analog converter (IDAC) to provide a constant current to the first integration capacitor. 7 . The method of claim 7 , wherein the IDAC is programmable. 8 . A mutual capacitance measurement circuit comprising: a first integration capacitor coupled to a first input of a comparator; a second integration capacitor coupled to a second input of a comparator; a reference voltage operatively coupled to the first and second integration capacitors, the reference voltage for resetting a voltage on the first and second integration capacitors during an initialization phase. a receive (RX) pin coupled to first electrode of a mutual capacitance, the RX pin for receiving positive and negative charge packets during an integration phase, the positive and negative charge packets applied to the second and first integration capacitors, respectively; a first current source coupled to the first integration capacitors, the first current source for charging the first integration capacitor until the voltage on the first integration capacitor is substantially equal to the charge on the second capacitor during a digitization phase; and time measurement logic coupled to and controlled an output of the comparator during the digitization phase, the output of the comparator derived from the voltages across the first and second integration capacitors, wherein an output of the time measurement logic is a digital value representative of the mutual capacitance. 9 . The mutual capacitance measurement circuit of claim 8 , wherein the mutual capacitance is formed between a second electrode coupled to a transmit (TX) signal generating circuit and the first electrode coupled to the RX pin. 10 . The mutual capacitance measurement circuit of claim 8 , wherein the RX pin is coupled to an analog multiplexor (AMUX), the AMUX for coupling at least one RX pin to an integration circuit including at least the first and second integration capacitors. 11 . The mutual capacitance measurement circuit of claim 10 , wherein the AMUX couples a plurality of RX pins to the integration circuit. 12 . The mutual capacitance circuit of claim 8 further comprising an AND gate coupled to the output of the comparator, the AND gate for providing control signals to a switch that couples the first current source to the first integration capacitor and for providing control signals to the time measurement logic. 13 . The mutual capacitance circuit of claim 8 further comprising a second current source coupled to the second integration capacitor, the second current source for providing a compensation signal to the second integration capacitor during the integration phase. 14 . The mutual capacitance circuit of claim 13 , wherein the compensation signal reduces the voltage on the second integration capacitor during the integration phase. 15 . A mutual capacitance measurement system comprising: at least one mutual capacitance comprising a first electrode and a second electrode; a mutual capacitance measurement circuit comprising: a transmit (TX) signal generator coupled to the first electrode, an receive (RX) channel coupled to the second electrode, an initialization circuit for applying a reference voltage to a first integration capacitor and a second integration capacitor, an integration circuit for receiving charge packets from the at least one mutual capacitance and integrating them on the first and second integration capacitors; a digitization circuit for converting voltages on the first and second integration capacitors to a digital value, the digital value representative of the capacitance value of the at least one mutual capacitance; and decision logic coupled to the mutual capacitance measurement circuit, the decision logic for detecting the presence or absence of a conductive object on or in proximity to the at least one mutual capacitance. 16 . The mutual capacitance measurement system of claim 15 further comprising: a microcontroller for controlling switch activation of a plurality of switches for initialization, integration, and digitization; a memory for storing program instructions for the microcontroller and an output of the decision logic; and a communication block for communicating outputs of the mutual capacitance measurement system to an external device. 17 . The mutual capacitance measurement system of claim 15 , wherein the first and second integration capacitors are external to the mutual capacitance measurement circuit. 18 . The mutual capacitance measurement system of claim 15 , wherein the first and second integration capacitors are disposed on an integrated circuit including the mutual capacitance measurement circuit. 19 . The mutual capacitance measurement system of claim 15 , wherein the mutual capacitance measurement circuit further comprises a first and second compensation circuits coupled to the first and second integration circuits, respectively, the first and second compensation circuits for providing a compensation signal to offset the charge packets. 20 . The mutual capacitance measurement system of claim 15 , wherein the TX signal generator alternately couples the first electrode to a first voltage and a second voltage.