Asynchronous interference detection in a capacitive sensing system

What is claimed is: 1 . A processing system for a capacitive sensing device, comprising: a sensor module comprising a receiver, coupled to a sensor electrode, configured to receive a capacitive sensing signal, the receiver including: an in-phase channel configured to mix the capacitive sensing signal with a local oscillator signal substantially in phase with the capacitive sensing signal; and a quadrature channel configured to mix the capacitive sensing signal with a phase-shifted signal near ninety degrees out of phase with the capacitive sensing signal; and a determination module configured to measure a change in capacitance in response to a demodulated signal of the in-phase channel concurrently with measuring a non-coherent signal in response to a demodulated signal of the quadrature channel. 2 . The processing system of claim 1 , wherein the non-coherent signal comprises the effects of interference. 3 . The processing system of claim 1 , wherein the non-coherent signal comprises the effects of a signal transmitted by an active pen proximate the capacitive sensing device. 4 . The processing system of claim 1 , wherein the capacitive sensing signal comprises a sinusoidal carrier, and wherein the determination module is configured to measure a change in capacitance using a square root of a sum of squares of the demodulated signals of the in-phase channel and the quadrature channel. 5 . The processing system of claim 1 , wherein the local oscillator signal comprises a continuous-time signal, and wherein the receiver further comprises a phase-shift circuit configured to generate the phase-shifted signal, the phase-shift circuit comprising one of an RC filter, a Hilbert transform filter, or a Weaver mixer. 6 . The processing system of claim 1 , wherein the local oscillator signal comprises a discrete-time signal generated by stepping through a lookup table, and wherein the receiver is configured to generate the phase-shifted signal by stepping through another lookup table or by stepping through the lookup table with an offset. 7 . The processing system of claim 1 , wherein the local oscillator signal comprises one of a sinusoidal signal, a square wave signal, or a multi-level harmonic-reject signal. 8 . The processing system of claim 1 , wherein the in-phase channel comprises a first mixer configured to mix the capacitive sensing signal with the local oscillator signal and a first low-pass filter configured to filter output of the first mixer, and wherein the quadrature channel comprises a second mixer configured to mix the capacitive sensing signal with the phase-shifted signal and a second low-pass filter configured to filter output of the second mixer. 9 . The processing system of claim 8 , wherein a bandwidth of the second low-pass filter is different than a bandwidth of the first low-pass filter. 10 . The processing system of claim 1 , wherein the sensor module is configured to shift a frequency of a clock signal used to generate the capacitive sensing signal based on the non-coherent signal. 11 . The processing system of claim 1 , wherein the sensor module is configured to enter a high-noise mode based on the non-coherent signal. 12 . An input device, comprising: a plurality of sensor electrodes; a processing system, coupled to the plurality of sensor electrodes, the processing system configured to: receive capacitive sensing signals; mix the capacitive sensing signals with a local oscillator signal substantially in-phase with the capacitive sensing signal to generate in-phase demodulated signals; mix the capacitive sensing signals with a phase-shifted signal near ninety degrees out of phase with the capacitive sensing signals to generate quadrature demodulated signals; measure changes in capacitance in response to the in-phase demodulated signals; and measure non-coherent signals in response to the quadrature demodulated signals. 13 . The input device of claim 12 , wherein the non-coherent signals comprise the effects of interference. 14 . The input device of claim 12 , wherein the non-coherent signals comprise the effects of a signal transmitted by an active pen proximate the input device. 15 . The input device of claim 12 , wherein the processing system is further configured to shift a frequency of a clock signal used to generate the capacitive sensing signals based on the non-coherent signals. 16 . The input device of claim 12 , wherein the processing system is further configured to enter a high-noise mode based on the non-coherent signals. 17 . A method of operating a capacitive sensing device having a plurality of sensor electrodes, the method comprising: receiving capacitive sensing signals derived from the plurality of sensor electrodes; mixing the capacitive sensing signals with a local oscillator signal substantially in-phase with the capacitive sensing signals to generate in-phase demodulated signals; mixing the capacitive sensing signals with a phase-shifted signal near ninety degrees out of phase with the capacitive sensing signals to generate quadrature demodulated signals; measuring changes in capacitance in response to the in-phase demodulated signals; and measuring non-coherent signals in response to the quadrature demodulated signals. 18 . The method of claim 17 , wherein the non-coherent signals comprise the effects of a signal transmitted by an active pen proximate the capacitive sensing device. 19 . The method of claim 17 , further comprising: shifting a frequency of a clock signal used to generate the capacitive sensing signals based on the non-coherent signals. 20 . The method of claim 17 , further comprising: entering a high-noise mode based on the non-coherent signals.