Capacitance sensor with noise rejection

1 . A sensor for providing an output signal that is a function of a sensed capacitance to which the sensor is connected through a connection node, the sensor comprising: a charger for repetitively applying first and second voltages to the connection node to charge the sensed capacitance to first and second charge values in first and second phases respectively; a sampler including at least a first current mirror for providing first and second sample current signals that are a function of the first and second charge values respectively; and an accumulator that comprises an accumulator capacitor for repetitively using the first and second sample current signals differentially in modifying a charge on the accumulator capacitor and providing an accumulator signal; wherein the accumulator signal is a progressive function of the sensed capacitance but cancels noise in the first and second sample current signals at frequencies less than a repetition rate of operation of the accumulator, and wherein the accumulator uses the accumulator signal to provide the output signal. 2 . The sensor of claim 1 , wherein the accumulator signal is a function of a voltage on the accumulator capacitor. 3 . The sensor of claim 1 , wherein the first current mirror converts current charging the sensed capacitance to the sample current signals. 4 . The sensor of claim 1 , wherein the first current mirror converts current discharging the sensed capacitance to the sample current signals. 5 . The sensor of claim 1 , wherein the accumulator includes at least a second current mirror for controlling the rate at which the accumulator signal varies. 6 . The sensor of claim 5 , wherein the second current mirror controls the rate at which the accumulator signal varies incrementally as a function of the first sample current signal, and controls supply of current to a third current mirror which controls the rate at which the accumulator signal varies decrementally as a function of the second sample current signal. 7 . The sensor of claim 1 for use with an array of capacitance elements, wherein the sensed capacitance is a self-capacitance between capacitance elements of the array and ground, and wherein the sensor includes switches for alternately connecting the charger and the sampler through the connection node to a selected capacitance element. 8 . The sensor of claim 7 , wherein the sampler is connected to the connection node to provide the first and second sample current signals while the charger is disconnected from the connection node. 9 . The sensor of claim 1 , wherein the accumulator modifies the voltage on the accumulator capacitor in repetitive steps, and wherein the accumulator includes a comparator for comparing the voltage on the accumulator capacitor with a reference voltage and a counter for counting the number of steps taken to reach the reference voltage. 10 . The sensor of claim 9 , further comprising a voltage generator for providing the first and second voltages and the reference voltage as a function of a common voltage supply. 11 . A capacitive sensing circuit comprising a sensor and an array of sensed capacitance elements, the sensor comprising: switches for conducting charge and discharge node currents to and from a selected capacitance element of the array through a connection node; a charger for repetitively providing the charge and discharge node currents in charging the sensed capacitance through the connection node to first and second charge values in first and second phases respectively; a sampler including at least a first current mirror for receiving the node currents and for providing first and second sample current signals that are a function of the first and second charge values respectively; and an accumulator for repetitively using the first and second sample current signals differentially in providing an accumulator signal; wherein the accumulator signal is a progressive function of the sensed capacitance but tends to cancel a noise in the first and second sample current signals at frequencies less than a repetition rate of operation of the accumulator. 12 . The circuit of claim 11 , wherein the accumulator includes an accumulator capacitor whose charge value is a progressive function of the sample current signals, and wherein the accumulator signal is a function of the charge value on the accumulator capacitor 13 . The circuit of claim 11 , wherein the first current mirror converts current charging the sensed capacitance to the sample current signals. 14 . The circuit of claim 11 , wherein the first current mirror converts current discharging the sensed capacitance to the sample current signals. 15 . The circuit of claim 11 , wherein the accumulator includes at least a second current mirror for controlling the rate at which the accumulator signal varies. 16 . The circuit of claim 15 , wherein the second current mirror controls the rate at which the accumulator signal varies incrementally as a function of the first sample current signal, and controls supply of current to a third current mirror that controls the rate at which the accumulator signal varies decrementally as a function of the second sample current signal. 17 . The circuit of claim 11 , wherein the sensed capacitance is a self-capacitance between capacitance elements of the array and ground, the sensed capacitance being a function of proximity of an object to the selected capacitance element, wherein the sensor includes switches for alternately connecting the charger and the sampler through the connection node to a selected capacitance element. 18 . The circuit of claim 17 , wherein the sampler is connected to the connection node to provide the first and second sample current signals while the charger is disconnected from the connection node. 19 . The circuit of claim 12 , wherein the accumulator modifies the voltage on the accumulator capacitor in repetitive steps, and wherein the accumulator includes a comparator for comparing the voltage on the accumulator capacitor with a reference voltage and a counter for counting the number of steps taken to reach the reference voltage. 20 . The circuit of claim 19 , wherein the sensor includes a voltage generator for providing the first and second voltages and the reference voltage as a function of a common voltage supply.