Microphone bias apparatus and method

The invention claimed is: 1. An apparatus for biasing a plurality of microphones, the apparatus comprising: a sensing circuit that actively senses a local ground reference for each of the plurality of microphones; an intermediate stage that receives a constant non-local reference voltage as an input and responsively provides a respective constant local reference signal with respect to each of the actively sensed local ground references; and for each microphone of the plurality of microphones, a respective microphone bias block that uses the respective constant local reference signal to generate a respective constant local microphone bias voltage to bias the microphone. 2. The apparatus of claim 1 , further comprising: wherein each respective constant local reference signal comprises a respective current; and wherein each respective microphone bias block uses the respective current to generate a respective constant local reference voltage for the microphone with respect to the actively sensed local ground reference of the microphone. 3. The apparatus of claim 2 , further comprising: for each microphone of the plurality of microphones, a respective driving stage for the microphone that uses the respective constant local reference voltage for the microphone as input and provides the respective constant local microphone bias voltage to bias the microphone. 4. The apparatus of claim 2 , further comprising: for each microphone of the plurality of microphones, a variable resistor-capacitor (RC) network that uses the respective current to generate a constant local reference voltage for the microphone; and wherein each of the RC networks is controllable in response to the respective actively sensed local ground reference to independently set the respective local microphone bias voltage to bias the respective microphone. 5. The apparatus of claim 4 , further comprising: wherein the apparatus comprises an integrated circuit; and wherein, for each microphone of the plurality of microphones, the respectively controllable variable resistor-capacitor (RC) network comprises a filter capacitor internal to the integrated circuit, thereby alleviating a need for an external filter capacitor for each of the microphones. 6. The apparatus of claim 2 , further comprising: a voltage-to-current conversion stage that converts the constant non-local reference voltage to a constant non-local reference current. 7. The apparatus of claim 6 , further comprising: a current mirror that uses the constant non-local reference current to generate the respective constant local reference currents for the plurality of microphones. 8. The apparatus of claim 7 , further comprising: a sensing circuit that actively senses, for each microphone of the plurality of microphones, the respective constant local microphone bias voltages. 9. The apparatus of claim 8 , further comprising: for each microphone of the plurality of microphones, a closed loop driving stage that uses as inputs the actively sensed constant local microphone bias voltage and the constant local reference voltage for the microphone with respect to the respective actively sensed local ground reference for the microphone to generate the respective constant local microphone bias voltage to bias the microphone. 10. The apparatus of claim 6 , further comprising: wherein the apparatus comprises an integrated circuit; and a filter capacitor external to the integrated circuit that couples the voltage-to-current conversion stage to a ground of the integrated circuit. 11. A method for biasing a plurality of microphones, the method comprising: actively sensing a local ground reference for each of the plurality of microphones; using a constant non-local reference voltage as an input to an intermediate stage that provides a respective constant local reference signal with respect to each of the actively sensed local ground references; and using, for each microphone of the plurality of microphones, the respective constant local reference signal to generate a respective constant local microphone bias voltage to bias the microphone. 12. The method of claim 11 , further comprising: wherein each respective constant local reference signal comprises a respective current; and using, for each microphone of the plurality of microphones, the respective current to generate a constant local reference voltage for the microphone with respect to the actively sensed local ground reference of the microphone. 13. The method of claim 12 , further comprising: wherein said using, for each microphone of the plurality of microphones, the respective constant local reference signal to generate a respective constant local microphone bias voltage to bias the microphone is performed by a respective driving stage for the microphone that uses the constant local reference voltage for the microphone as input and provides the respective constant local microphone bias voltage. 14. The method of claim 12 , further comprising: wherein said using, for each microphone of the plurality of microphones, the respective current to generate a constant local reference voltage for the microphone is performed by a variable resistor-capacitor (RC) network for the microphone; and controlling, for each microphone of the plurality of microphones, the variable RC network for the microphone to independently set the local microphone bias voltage to bias the microphone in response said actively sensing a local ground reference. 15. The method of claim 14 , further comprising: wherein the method is performed by an integrated circuit; and wherein, for each microphone of the plurality of microphones, the respectively controllable variable resistor-capacitor (RC) network comprises a filter capacitor internal to the integrated circuit, thereby alleviating a need for an external filter capacitor for each of the microphones. 16. A method for biasing a plurality of microphones, the method comprising: actively sensing a local ground reference for each of the plurality of microphones; using a constant non-local reference voltage to generate a respective constant local reference current for each of the plurality of microphones; using, for each microphone of the plurality of microphones, the constant local reference current for the microphone to generate a constant local reference voltage for the microphone with respect to the respective actively sensed local ground reference for the microphone; and using, for each microphone of the plurality of microphones, the constant local reference voltage for the microphone to generate a constant local microphone bias voltage to bias the microphone. 17. The method of claim 16 , further comprising: converting, by a voltage-to-current conversion stage, the constant non-local reference voltage to a constant non-local reference current; and using the constant non-local reference current to generate the constant local reference current for each of the plurality of microphones. 18. The method of claim 17 , wherein using the constant non-local reference current to generate the constant local reference current for each of the plurality of microphones is performed by a current mirror. 19. The method of claim 16 , further comprising: actively sensing, for each microphone of the plurality of microphones, the constant local microphone bias voltage. 20. The method of claim 19 , further comprising: wherein said using, for each microphone of the plurality of microphones, the constant local refere