Enhanced auto-monitoring circuit and method for an electrical device

What is claimed is: 1. A circuit interrupting device comprising: a pair of conductive line terminals for connecting to an AC power source; a pair of line conductors, each electrically coupled to a respective one of said conductive line terminals; a test conductor electrically isolated from said pair of line conductors; a pair of conductive face terminals configured to receive mating conductors of an electrical load; a fault detection circuit including at least one transformer coil through which each of said pair of line conductors and said test conductor traverse, said fault detection circuit being configured to detect a net current passing through the at least one transformer and generate a fault detection signal; an interrupting device operable to electrically couple said pair of line conductors and said pair of face terminals; a solenoid with a first winding and a second winding, said solenoid being operable to engage said interrupting device to electrically decouple said pair of line conductors and said pair of face terminals, wherein said first and second windings are wound in the same direction around a bobbin and provide a combined electromagnetic force in a first direction when both of said first winding and said second windings are electrically energized; and an auto-monitoring circuit electrically coupled to said fault detection circuit and said solenoid, wherein said auto-monitoring circuit generates a test net current on said test conductor and determines whether said fault detection circuit successfully detects the test net current passing through the at least one transformer coil. 2. The circuit interrupting device recited in claim 1 , further comprising: a first switching device electrically coupled between said actuator and said fault detection circuit, and being activated when said fault detection circuit detects a net current passing through the at least one transformer coil; a second switching device electrically coupled between said actuator and said auto-monitoring circuit, and being activated when said fault detection circuit fails to detect a net current passing through the at least one transformer coil; and a third switching device electrically coupled between said test conductor and said auto-monitoring circuit. 3. The circuit interrupting device recited in claim 2 , further comprising a reset switch electrically coupled between said fault detection circuit and said first switching device, and being activated when said reset switch is closed. 4. The circuit interrupting device recited in claim 2 , wherein said auto-monitoring circuit controllably closes said third switching device to generate said test net current on said test conductor, and controllably opens said third switching device to stop said test net current from being generated on said test conductor. 5. The circuit interrupting device recited in claim 1 , wherein said fault detection circuit generates first and second output signals, said first output signal being electrically coupled to a first switch for driving said solenoid when said net current passes through the at least one transformer and said second output signal being electrically coupled to said auto-monitoring circuit. 6. The circuit interrupting device recited in claim 5 , wherein said second output signal is generated before said first output signal is generated, said auto-monitoring circuit determining whether said test net current was detected by said fault detection circuit based on said second output signal. 7. The circuit interrupting device recited in claim 6 , wherein said auto-monitoring circuit includes a programmable device having a first input/output (I/O) port that is controllably switched between being an input port and an output port, said second output signal of said fault detection circuit being input to said first I/O port when it is controlled to be an input. 8. The circuit interrupting device recited in claim 1 , wherein said auto-monitoring circuit includes a programmable device programmed to periodically run an auto-monitoring routine, said auto-monitoring routine including generating the test net current on said test conductor on either a positive half-cycle of the AC power or a negative half-cycle of the AC power, and determining whether said fault detection circuit successfully detected the test net current passing through the at least one transformer coil, said programmable device further maintaining a failure count representing a number of times the fault detection circuit failed to detect the test net current. 9. The circuit interrupting device recited in claim 8 , further comprising an end-of-life indicator controlled by said auto-monitoring circuit, and being activated when said failure count exceeds a predetermined threshold. 10. The circuit interrupting device recited in claim 3 , further comprising a status determining circuit configured to determine one or more of whether power is available at the fault detection circuit, whether power is available at the face terminals, and whether the reset switch has been activated. 11. An auto-monitoring circuit for automatically monitoring the performance of a ground fault circuit interrupting (GFCI) device comprising: a microprocessor configured to periodically run an auto-monitoring routine based on a stored program; a driver coupled to said microprocessor and being operable to initiate a test signal representative of a ground fault each time said auto-monitoring routine is run; and an end-of-life indicator coupled to said microprocessor and being operable to indicate that the GFCI device has failed to detect said test signal in a predetermined number of consecutive runs of said auto-monitoring routine, wherein said microprocessor directly drives said end-of-life indicator; a solenoid with a first winding and a second winding having separately driven primary and fail-safe operations, wherein said first and second windings are wound in the same direction around a bobbin, wherein said microprocessor is operable to activate said fail-safe operation by electrically energizing both of said first winding second windings at the same time to produce a combined electromagnetic force in a first direction. 12. The auto-monitoring circuit recited in claim 11 , wherein said microprocessor includes at least one input/output (I/O) port configurable to be either an input or an output port based on said auto-monitoring routine, one of said configurable I/O ports being configured as an input to an analog-to-digital converter to receive a detection signal indicating whether or not said test signal has been detected.