Impedance characteristic circuit for electrochemical sensor

The claimed invention is: 1. An impedance characteristic sensor interface circuit for independently delivering a differential stable bias signal component and a differential time-varying AC excitation signal component for testing an impedance of an electrochemical sensor having a sensor input node, first and second differential sensor feedback nodes, and a sensor output node, the sensor interface circuit including: an impedance excitation amplifier circuit, including: a first differential pair of inputs, coupled to receive the differential time-varying AC excitation signal component for communication onto first and second amplifier input nodes during a sensor impedance testing mode; a second differential pair of inputs, coupled to receive the differential stable bias signal component for communication onto the first and second amplifier input nodes; and a third differential pair of inputs, coupled to receive a feedback signal from the differential sensor feedback nodes for communication onto the first and second amplifier inputs nodes; and a sensor response amplifier circuit, coupled to the sensor for receiving a response signal to the differential time-varying AC excitation signal component, during the sensor impedance testing mode, for communication to a sensor response signal output node. 2. The sensor interface circuit of claim 1 , comprising a first digital-to-analog converter (DAC) circuit, to convert a first digital input signal into a first analog signal for providing the differential time-varying AC excitation signal component. 3. The sensor interface circuit of claim 2 , comprising a second DAC circuit, to convert a second digital input signal into a second analog signal for providing the differential stable bias signal component. 4. The sensor interface circuit of claim 3 , wherein the second DAC circuit is also used to provide the differential stable bias signal component during an operating mode of the sensor during which the differential time-varying AC excitation signal component is not applied. 5. The sensor interface circuit of claim 3 wherein the second DAC circuit includes outputs to which shunt capacitors are respectively coupled. 6. The sensor interface circuit of claim 2 , comprising an attenuating amplifier circuit to attenuate an output signal of the first DAC for providing the differential time-varying AC excitation signal component onto the first and second amplifier input nodes. 7. The sensor interface circuit of claim 1 , comprising a load resistor to couple the sensor to at least one of (1) a transimpedance amplifier input of the sensor response amplifier circuit or (2) at least one of the differential sensor feedback nodes. 8. The sensor interface circuit of claim 1 , wherein the differential time-varying AC excitation signal component is frequency-varying during the sensor impedance testing mode. 9. The sensor interface circuit of claim 1 , wherein the differential stable bias signal component is temperature compensated. 10. A method of determining usability of an electrochemical sensor by determining an impedance associated with the electrochemical sensor, the method including: delivering a differential time-varying AC excitation signal component to first and second amplifier input nodes for driving an excitation signal into the sensor during a sensor impedance test; separately delivering a differential stable bias signal component to the first and second amplifier input nodes for biasing the first and second amplifier input nodes while driving the excitation signal into the sensor during the sensor impedance test; communicating a differential feedback signal from the sensor to the first and second amplifier input nodes while driving the excitation signal into the sensor; and measuring a response from the sensor while driving the excitation signal into the sensor during the sensor impedance test. 11. The method of claim 10 , comprising: converting a first digital input signal into a first analog signal for providing the differential time-varying AC excitation signal component during the sensor impedance test; and converting a second digital input signal into a second analog signal for providing the differential stable bias signal component during the sensor impedance test. 12. The method of claim 11 , further comprising also using the second analog signal for providing the differential stable bias signal component during an operating mode of the sensor during which the differential time-varying AC signal component is not applied. 13. The method of claim 11 , comprising attenuating the first analog signal for providing the differential time-varying AC excitation signal component during the sensor impedance test. 14. The method of claim 11 , comprising converting a current from the sensor in response to the differential time-varying AC excitation signal component into a voltage to provide an indication of a sensor characteristic related to usability of the sensor. 15. The method of claim 11 , comprising varying a frequency of the differential time-varying AC signal component during the sensor impedance test. 16. The method of claim 11 , comprising temperature compensating the differential stable bias signal component. 17. The method of claim 11 , comprising providing at least one of a proportional-to-absolute-temperature (PTAT) or complementary-to-absolute-temperature (CTAT) signal to generate the differential stable bias signal component. 18. An impedance characteristic sensor interface circuit for independently delivering a differential stable bias signal component and a differential time-varying AC excitation signal component for testing an impedance of an electrochemical sensor, the sensor interface circuit including: an impedance excitation amplifier circuit, including: a first digital-to-analog converter (DAC) circuit, to convert a first digital input signal into a first analog signal for providing the differential time-varying AC excitation signal component during a sensor impedance testing mode; a second DAC circuit, to convert a second digital input signal into a second analog signal for providing the differential stable bias signal component during the sensor impedance testing mode; and a sensor response amplifier circuit, coupled to the sensor for receiving a response signal to the differential time-varying AC excitation signal component, during the sensor impedance testing mode. 19. The sensor interface circuit of claim 18 , comprising: a first differential pair of inputs, coupled to receive the differential time-varying AC excitation signal component for communication onto first and second amplifier input nodes during a sensor impedance testing mode; a second differential pair of inputs, coupled to receive the differential stable bias signal component for communication onto the first and second amplifier input nodes; and a third differential pair of inputs, coupled to receive a feedback signal from the differential sensor feedback nodes for communication onto the first and second amplifier inputs nodes. 20. The sensor interface circuit of claim 19 , in combination with an electrochemical sensor including a reference electrode, a working or sensing electrode, and a counter or auxiliary electrode, wherein: the counter or auxiliary electrode is coupled to the sensor interface circuit to receive the differential time-varying AC excitation signal component superimposed on the differential stable bias signal component during the sensor impedance testing mode; the