Sensor system and integrated heater-sensor for measuring and controlling performance of a heater system

What is claimed is: 1. A fluid sensor system for a heating system, the sensor system comprising: a probe having a finite length a portion of which is immersed in a fluid, the probe comprising a resistive heating element and a fluid temperature sensor for measuring one or more performance characteristics, wherein the fluid temperature sensor is configured to measure a fluid temperature, and the resistive heating element is operable as a heater to create a temperature differential along the length of the probe to detect the fluid, and wherein the resistive heating element is operable to measure a fluid level; and a control system configured to operate the probe and determine the one or more performance characteristics of the heating system based on at least one of an electrical response of the resistive heating element operating as the sensor and an electrical response of the fluid temperature sensor, wherein the control system is configured to: apply a first power amount to the resistive heating element to generate the temperature differential when the fluid temperature is substantially the same as an ambient temperature; and apply a second power amount less than the first power amount to measure resistance of the resistive heating element when the fluid temperature is different from the ambient temperature. 2. The fluid sensor system of claim 1 wherein the one or more performance characteristics include at least one of the fluid level and the fluid temperature. 3. The fluid sensor system of claim 1 , wherein the control system is configured to determine the fluid level based on the fluid temperature and predetermined information that correlates a given resistance and a given temperature with a given fluid level. 4. The fluid sensor system of claim 1 , wherein the probe further comprises an ambient temperature sensor to measure the ambient temperature, wherein the ambient temperature sensor is disposed at a portion of the probe that is away from the fluid. 5. The fluid sensor system of claim 4 , wherein the ambient temperature sensor is a thermocouple. 6. The fluid sensor system of claim 1 , wherein the probe further comprises a resistance temperature detector (RTD), and at least one of the resistive heating element and the fluid temperature sensor is connected to the RTD. 7. The fluid sensor system of claim 1 , wherein the probe further comprises a four wire resistance temperature detector (RTD), wherein a first loop wire having a high temperature coefficient resistance (TCR) is connected to the RTD to form the resistive heating element and a second loop wire is connected to the RTD to form the fluid temperature sensor. 8. The fluid sensor system of claim 1 , wherein the probe further comprises a limit sensor for detecting a maximum fluid temperature. 9. The fluid sensor system of claim 1 , wherein the fluid temperature sensor is a thermocouple. 10. A fluid sensor system for a heating system, the sensor system comprising: a probe having a finite length a portion of which is immersed in a fluid, the probe comprising a resistive heating element to detect the fluid and a fluid temperature sensor to measure a fluid temperature, wherein the resistive heating element is operable as a heater to create a temperature differential along the length of the probe to detect the fluid, and wherein the resistive heating element is operable to measure a fluid level; and a control system configured to determine one or more performance characteristics of the heating system based on at least one of an electrical response from the resistive heating element operating as a sensor and an electrical response of the fluid temperature sensor, and on predetermined information, wherein the control system is configured to operate the resistive heating element as the heater in response to the fluid temperature being substantially same as an ambient temperature, wherein the control system is configured to apply at least one of: a first power amount to the resistive heating element to generate the temperature differential when the fluid temperature is substantially the same as the ambient temperature, and a second power amount less than the first power amount to the resistive heating element to measure a resistance of the resistive heating element when the fluid temperature is different from the ambient temperature. 11. The fluid sensor system of claim 10 , wherein the control system is configured to determine the fluid level, as a performance characteristic, based on the fluid temperature determined based on the electrical response of the fluid temperature sensor, the resistance of the resistive heating element, and predetermined information that correlates a given resistance and a given fluid temperature with a given fluid level. 12. The fluid sensor system of claim 10 , wherein the probe further comprises an ambient temperature sensor to measure the ambient temperature. 13. The fluid sensor system of claim 10 , wherein the probe further comprises a resistance temperature detector (RTD), and at least one of the resistive heating element and the fluid temperature sensor is connected to the RTD. 14. The fluid sensor system of claim 10 , wherein the probe further comprises a limit sensor for detecting a maximum fluid temperature, and the control system is configured to measure the fluid temperature based on an electrical response of the limit sensor and determine whether the fluid temperature is above a predefined limit. 15. A heater system comprising: the sensor system of claim 10 ; a heater operable to heat the fluid; and a heater control system in communication with the control system of the sensor system, and configured to control the heater based on the performance characteristics. 16. A heater system comprising: an integrated heater device comprising at least one multiportion resistive element, the at least one multiportion resistive element having a first portion defined by a first conductive material and a second portion defined by a second conductive material having a lower temperature coefficient of resistance (TCR) than that of the first conductive material, wherein the multiportion resistive element is operable as a heater to generate heat and as a sensor for measuring a fluid temperature, and wherein the first portion of the multiportion resistive element is configured to extend along a designated area to measure one or more performance characteristics; and a control system configured to operate the multiportion resistive element to measure an electrical response of the multiportion resistive element, wherein the control system is configured to: determine the one or more performance characteristics of the heating system based on the electrical response; apply a first power amount to the multiportion resistive element when the fluid temperature is substantially the same as an ambient temperature and when the integrated heater device is operable as the heater; and apply a second power amount less than the first power amount to measure resistance of the multiportion resistive heating element when the fluid temperature is different from the ambient temperature and when the integrated heater device is operable as the sensor. 17. The heater system of claim 16 further comprising a first member and a second member having a different Seebeck coefficient than that of the first member, wherein the first member and the second member form a temperature sensing junction to measure a temperature at a first location as a second performance characteristic.