Digital non-linearity compensation in a silicon microphone

What is claimed is: 1. A digital microphone comprising: an analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC blocker component; and a nonlinear compensation component coupled to the digital low pass filter for providing a digital output signal, wherein a transfer function of the nonlinear compensation component comprises a second order polynomial, and wherein the nonlinear compensation component comprises a multiplier coupled to an input of the nonlinear compensation component, a gain stage coupled to an output of the multiplier, and an adder coupled to an output of the gain stage and coupled to the input of the nonlinear compensation component. 2. The digital microphone of claim 1 , further comprising a microelectromechanical system (MEMS) device coupled to an input of the ADC. 3. The digital microphone of claim 2 , wherein the MEMS device comprises a capacitive MEMS microphone device. 4. The digital microphone of claim 1 , wherein the ADC comprises a sigma-delta ADC. 5. The digital microphone of claim 1 , wherein the digital microphone is fabricated in an Application Specific Integrated Circuit (ASIC). 6. The digital microphone of claim 1 , further comprising another digital filter and a digital modulator interposed between the nonlinear compensation component and an output of the digital microphone. 7. The digital microphone of claim 6 , wherein the digital modulator comprises a single-bit digital modulator. 8. A microphone comprising: a sigma-delta analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC block component; and a nonlinear compensation component coupled to the digital low pass filter for providing a linearized digital output signal, wherein the nonlinear compensation component is in at least one feedback loop with a loop filter or an error feedback structure, wherein a transfer function of the nonlinear compensation component comprises a second order polynomial, and wherein the nonlinear compensation component comprises a multiplier coupled to an input of the nonlinear compensation component, a gain stage coupled to an output of the multiplier, and an adder coupled to an output of the gain stage and coupled to the input of the nonlinear compensation component. 9. A method comprising: converting an analog signal into a first digital signal, wherein the analog signal includes nonlinearities; removing an offset from the first digital signal to provide a second digital signal; low pass filtering the second digital signal to provide a third digital signal; and compensating the third digital signal using a nonlinear transfer function fitted to the nonlinearities in the analog signal to provide a fourth digital signalusing a nonlinear compensation component, wherein a transfer function of the nonlinear compensation component comprises a second order polynomial, and wherein the nonlinear compensation component comprises a multiplier coupled to an input of the nonlinear compensation component, a gain stage coupled to an output of the multiplier, and an adder coupled to an output of the gain stage and coupled to the input of the nonlinear compensation component. 10. The method of claim 9 , wherein the nonlinear transfer function is in a feedback loop with a loop filter. 11. The method of claim 9 , wherein the nonlinear transfer function is in a first feedback loop coupled to a second feedback loop, and wherein an error feedback structure is in the second feedback loop. 12. A digital microphone comprising: an analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC blocker component; and a nonlinear compensation component coupled to the digital low pass filter for providing a digital output signal, wherein a transfer function of the nonlinear compensation component comprises a third order polynomial, and wherein the nonlinear compensation component comprises a first multiplier coupled to an input of the nonlinear compensation component, a first gain stage coupled to an output of the first multiplier, a second multiplier coupled to the input of the nonlinear compensation component and coupled to the output of the first multiplier, a second gain stage coupled to an output of the second multiplier, an adder coupled to an output of the first gain stage, coupled to an output of the second gain stage, and coupled to the input of the nonlinear compensation component. 13. The digital microphone of claim 12 , further comprising a microelectromechanical system (MEMS) device coupled to an input of the ADC. 14. The digital microphone of claim 12 , wherein the ADC comprises a sigma- delta ADC. 15. The digital microphone of claim 12 , further comprising another digital filter and a digital modulator interposed between the nonlinear compensation component and an output of the digital microphone. 16. The digital microphone of claim 15 , wherein the digital modulator comprises a single-bit digital modulator. 17. A digital microphone comprising: an analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC block component; and a nonlinear compensation component coupled to the digital low pass filter for providing a digital output signal, wherein the nonlinear compensation component comprises a first summer having a first input coupled to an input of the nonlinear compensation component, and an output configured for providing a linearized output signal, a second summer having a first input coupled to the output of the first summer, a nonlinear compensation subcomponent coupled to the output of first summer, and an output coupled to a second input of the second summer, and an error feedback structure coupled between an output of the second summer and an input of the first summer. 18. The digital microphone of claim 17 , wherein the error feedback structure comprises an integrator. 19. The digital microphone of claim 17 , wherein the error feedback structure comprises a first integrator in series with a second integrator. 20. The digital microphone of claim 19 , further comprising: a third summer having a first input coupled to the second integrator; and a third gain stage coupled between an output of the first integrator and a second input of the third summer.