System and method for sensor diagnostics during functional operation

What is claimed is: 1. A system comprising: a magnetic field sense element configured to detect an external magnetic field; a magnetic field source proximate the magnetic field sense element and configured to provide a reference magnetic field that is detectable by the magnetic sense element, wherein the magnetic field sense element is configured to produce a composite signal having a reference signal portion and a measurement signal portion, the reference signal portion being indicative of the reference magnetic field and the measurement signal portion being indicative of the external magnetic field; a power supply coupled with the magnetic field source and configured to provide a supply current through the magnetic field source for continuously generating the reference magnetic field while the system is in an operational mode; a processing circuit coupled with the magnetic sense element, the processing circuit being configured to process the composite signal to produce a measurement output signal indicative of the external magnetic field, wherein processing circuit comprises an analog-to-digital converter (ADC) system configured to convert the composite signal to a digitized composite signal; and a qualification circuit coupled with the processing circuit at multiple test points, the qualification circuit being configured to detect the reference signal portion at the multiple test points and determine an operability of at least a portion of the system from the reference signal portion detectable at each of the multiple test points, wherein the multiple test points include a first test point, the first test point including a first interconnect between the ADC system and the qualification circuit, wherein the qualification circuit is configured to detect a digitized qualification reference signal portion of the reference signal portion in the digitized composite signal and produce a first error flag when the digitized qualification reference signal portion is outside of a first expected signal range. 2. The system of claim 1 wherein the processing circuit comprises a first filter element configured to remove the reference signal portion from the composite signal to produce the measurement output signal from the measurement signal portion of the composite signal. 3. The system of claim 1 wherein the qualification circuit comprises a second filter element configured to remove the measurement signal portion from the composite signal to produce the reference signal portion prior to determining the operability of the at least a portion of the system. 4. The system of claim 1 wherein the ADC system comprises: a sigma-delta ADC configured to receive the composite signal and convert the composite signal to a digitized intermediate composite signal; and a decimation structure configured to receive the digitized intermediate composite signal and process the digitized intermediate composite signal to produce the digitized composite signal, wherein a condition in which the digitized qualification reference signal portion is outside of the first expected signal range indicates one of a sigma-delta ADC fault and a decimation structure fault. 5. The system of claim 1 wherein the processing circuit further comprises: a linearization circuit configured to produce a linearized composite signal in response to the digitized composite signal; and the multiple test points a second test point, the second test point including a second interconnect between the linearization circuit and the qualification circuit, wherein the qualification circuit is further configured to detect a linearized qualification reference signal portion of the reference signal portion in the linearized composite signal and produce a second error flag when the linearized qualification reference signal portion is outside of a second expected signal range. 6. The system of claim 5 wherein the linearization circuit further comprises a stray field compensation section configured to compensate for a stray field signal portion superimposed on the composite signal, the stray field signal portion being indicative of a stray magnetic field in the presence of the external magnetic field, wherein a condition in which the linearized qualification reference signal portion is outside of the second expected signal range indicates at least one of a linearization circuit fault and insufficient suppression of the stray field signal portion at the stray field compensation section. 7. The system of claim 1 wherein the processing circuit further comprises: a signal conditioning circuit configured to compensate for a variable signal portion within the digitized composite signal to produce a compensated composite signal; and a comparator element having inputs coupled with the signal conditioning circuit, the comparator element being configured to produce a third error flag when the compensated composite signal is outside of a third expected signal range. 8. The system of claim 1 wherein the system selectively functions in-situ in either of the operational mode and a standby mode, wherein the external magnetic field is available for detection by the magnetic sense element in the operational mode, the external magnetic field is not available for detection by the magnetic sense element in the standby mode, and the power supply is configured to provide the supply current when the system is in both of the operational and standby modes. 9. The system of claim 8 the processing circuit is further configured to produce the measurement output signal indicative of the external magnetic field when the system is in the operational mode, and the processing circuit is further configured to process the reference signal portion of the composite signal to produce a reference output signal indicative of the reference magnetic field when the system is in the standby mode. 10. A system comprising: a magnetic field sense element configured to detect an external magnetic field, wherein the system selectively functions in-situ in either of the operational mode and a standby mode, the external magnetic field is available for detection by the magnetic sense element in the operational mode, and the external magnetic field is not available for detection by the magnetic sense element in the standby mode; a magnetic field source proximate the magnetic field sense element and configured to provide a reference magnetic field that is detectable by the magnetic sense element, wherein the magnetic field sense element is configured to produce a composite signal having a reference signal portion and a measurement signal portion, the reference signal portion being indicative of the reference magnetic field and the measurement signal portion being indicative of the external magnetic field; a power supply coupled with the magnetic field source and configured to provide a supply current through the magnetic field source for continuously generating the reference magnetic field while the system is in the operational and standby modes; and a processing circuit coupled with the magnetic sense element, the processing circuit being configured to process the measurement signal portion of the composite signal to produce a measurement output signal indicative of the external magnetic field when the system is in the operational mode, and the processing circuit being further configured to process the reference signal portion of the composite signal to produce a reference output signal indicative of the reference magnetic field when the system is in the standby mode, wherein the magnetic sense element, the magnetic field source, the power supply, and the processing circuit are implemented within a speed sensor system, and the standby m