Oxygen sensor system and method

We claim: 1. An oxygen sensor system including an oxygen sensor and associated circuitry connected thereto, said an oxygen sensor including a reference cell, said associated circuitry configured to measure the impedance of said reference cell at time intervals, wherein said time intervals include a random component. 2. An oxygen sensor system as claimed in claim 1 wherein said associated circuitry includes a connection to said reference cell, and is configured to determine the temperature of said oxygen sensor based on the measurement of impedance of said reference cell at said time intervals, and control a sensor heater dependent on said determined temperature. 3. An oxygen sensor system as claimed in claim 2 wherein said associated circuitry comprises means configured to receive a signal dependent on the voltage of said reference cell, process said signal, determine an PWM signal therefrom, and output aid PWM signal to control said sensor heater. 4. An oxygen sensor system as claimed in claim 3 wherein said associated circuitry further comprises a processor and intermediate circuitry connected between said oxygen sensor and said processor. 5. An oxygen sensor system as claimed in claim 4 where said intermediate circuitry includes a connection from said reference cell, and is configured to output a voltage to said processor based on the impedance of said reference cell. 6. An oxygen sensor system as claimed in claim 5 , wherein said processor is configured to send temperature/impedance measurement commands to said intermediate circuitry, and said intermediate circuitry is configured to send a signal to said processor consequent to receiving said measurement command from said processor. 7. An oxygen sensor system as claimed in claim 6 including random time delay generating means configured to determine a random time delay, and where said intermediate circuitry is configured to output a voltage signal to said processor, said voltage signal being indicative of the reference cell impedance at a time point, said time point being the time point of reception of the measurement command plus said random time delay. 8. An oxygen sensor system as claimed in claim 7 wherein said intermediate circuitry includes said random time delay generating means, and further includes a switch configured to control the output voltage indicative of the impedance of said reference cell to said processor, dependent on the random time delay. 9. An oxygen sensor system as claimed in claim 1 wherein said associated circuitry comprises means configured to receive a signal dependent on the voltage of said reference cell, process said signal, determine an PWM signal therefrom, and output aid PWM signal to control said sensor heater. 10. An oxygen sensor system as claimed in claim 9 wherein said associated circuitry further comprises a processor and intermediate circuitry connected between said oxygen sensor and said processor. 11. An oxygen sensor system as claimed in claim 10 where said intermediate circuitry includes a connection from said reference cell, and is configured to output a voltage to said processor based on the impedance of said reference cell. 12. An oxygen sensor system as claimed in claim 11 , wherein said processor is configured to send temperature/impedance measurement commands to said intermediate circuitry, and said intermediate circuitry is configured to send a signal to said processor consequent to receiving said measurement command from said processor. 13. An oxygen sensor system as claimed in claim 12 including random time delay generating means configured to determine a random time delay, and where said intermediate circuitry is configured to output a voltage signal to said processor, said voltage signal being indicative of the reference cell impedance at a time point, said time point being the time point of reception of the measurement command plus said random time delay. 14. An oxygen sensor system as claimed in claim 13 wherein said intermediate circuitry includes said random time delay generating means, and further includes a switch configured to control the output voltage indicative of the impedance of said reference cell to said processor, dependent on the random time delay. 15. An oxygen sensor system as claimed in claim 1 , wherein said processor is configured to send temperature/impedance measurement commands to said intermediate circuitry, and said intermediate circuitry is configured to send a signal to said processor consequent to receiving said measurement command from said processor. 16. An oxygen sensor system as claimed in claim 15 including random time delay generating means configured to determine a random time delay, and where said intermediate circuitry is configured to output a voltage signal to said processor, said voltage signal being indicative of the reference cell impedance at a time point, said time point being the time point of reception of the measurement command plus said random time delay. 17. An oxygen sensor system as claimed in claim 16 wherein said intermediate circuitry includes said random time delay generating means, and further includes a switch configured to control the output voltage indicative of the impedance of said reference cell to said processor, dependent on the random time delay. 18. A method of controlling the temperature of an oxygen sensor, said oxygen sensor including a reference cell and a heater, said method comprising a) measuring the impedance of said reference cell at time intervals; b) determining the temperature of said sensor based on the measurement of impedance of said reference cell at said time intervals; c) controlling said heater dependent on said determined temperature; wherein said time intervals include a random component. 19. A method as claimed in claim 18 wherein said oxygen sensor is part of an oxygen sensor system which includes a processor and intermediate circuitry connected between said oxygen sensor and said processor, said intermediate circuit configured to provides a signal indicative of said impedance to said processor. 20. A method as claimed in claim 19 wherein step a) comprises i) sending out temperature measurement commands at regular intervals to said intermediate circuitry from said processor; ii) sending impedance measurements of said reference cell consequent to said temperature measurement commands to said processor from said intermediate circuitry; said impedance measurements being taken at a random delay time after corresponding temperature measurement commands.