Safety circuit and brush holder for preventing fault conditions in an alternator

What is claimed is: 1. A fault protection circuit for an alternator, comprising: a first switch having a first terminal electrically connected to an intermediate supply node, a second terminal electrically connected to a rotor in the alternator, and a third terminal, wherein the first switch is configured to provide an excitation current to the rotor as a function of an excitation current control signal applied to the third terminal and a voltage at the intermediate supply node, so as to regulate an output voltage of the alternator; an alternator controller circuit comprising an excitation current controller configured to generate the excitation current control signal; a supervision circuit configured to detect a fault condition of the first switch and, responsive to this detection, generate a fault indication signal; and a second switch electrically connected directly in series between the intermediate supply node and a supply voltage, the second switch configured to continuously disconnect the supply voltage from the intermediate supply node so long as the fault indication signal is active, and wherein the output voltage of the alternator provides the supply voltage. 2. The fault protection circuit of claim 1 wherein the fault indication signal is an overvoltage indication signal that indicates that the output voltage of the alternator has exceeded a predetermined limit. 3. The fault protection circuit of claim 1 wherein the fault indication signal indicates that a highly resistive short of 100 kohms or more exists between the first terminal and the second terminal of the first switch. 4. The fault protection circuit of claim 1 , wherein the supervision circuit is disposed in a different semiconductor die than the alternator controller circuit. 5. The fault protection circuit of claim 1 , wherein the supervision circuit and the second switch are disposed in the same semiconductor die. 6. The fault protection circuit of claim 1 , wherein the fault indication signal is received by the alternator controller circuit from an electronic control unit (ECU). 7. The fault protection circuit of claim 1 , further comprising: a communication interface circuit configured to receive the fault indication signal from an electronic control unit (ECU) and to send the fault indication signal to the second switch, wherein the communication interface circuit is disposed on a different semiconductor die than the alternator controller circuit. 8. The fault protection circuit of claim 7 , wherein the fault indication signal is received by the communication interface circuit over a serial bus. 9. The fault protection circuit of claim 8 , wherein the serial bus is a Local Interconnect Network (LIN) bus. 10. The fault protection circuit of claim 8 , wherein the serial bus is a Controller Area Network (CAN) bus. 11. The fault protection circuit of claim 7 , wherein the fault indication signal is received by the communication interface circuit over a dedicated line separate from a shared serial bus over which the ECU communicates with the alternator controller circuit. 12. The fault protection circuit of claim 1 , wherein the excitation current control signal is a pulse-width modulated (PWM) signal. 13. The fault protection circuit of claim 1 , wherein the alternator output voltage is directly connected to the supply voltage at a common node. 14. The fault protection circuit of claim 1 , wherein the alternator charges a battery and the supply voltage is provided by the battery. 15. The fault protection circuit of claim 1 , wherein the first switch is a metal-oxide semiconductor field-effect transistor (MOSFET) and the third terminal of the first switch is a gate of the MOSFET. 16. The fault protection circuit of claim 15 , wherein the first switch is an N-channel MOSFET and the second switch disconnects the supply voltage from a drain of the N-channel MOSFET. 17. The fault protection circuit of claim 15 , wherein the first switch is a double-diffused MOSFET. 18. A brush holder for use in an alternator, the brush holder comprising: a housing retaining a brush configured to conduct an excitation current to a rotor in the alternator; a first switch retained by the housing, the first switch having a first terminal electrically connected to an intermediate supply node, a second terminal electrically connected to the brush, and a third terminal, wherein the first switch is configured to provide the excitation current to the rotor via the brush as a function of an excitation current control signal applied to the third terminal and a voltage at the intermediate supply node, so as to regulate an output voltage of the alternator; an alternator controller circuit retained by the housing, the alternator controller circuit comprising an excitation current controller configured to generate the excitation current control signal; a supervision circuit configured to detect a fault condition of the first switch and, responsive to this detection, generate a fault indication signal; and a second switch retained by the housing, the second switch electrically connected directly in series between the intermediate supply node and a supply voltage, the second switch configured to continuously disconnect the supply voltage from the intermediate supply node so long as the fault indication signal is active, and wherein the output voltage of the alternator provides the supply voltage. 19. The brush holder of claim 18 , wherein the supervision circuit and the second switch are disposed in the same semiconductor die. 20. A method in an alternator for mitigating a fault condition of the alternator, the method comprising: providing an excitation current to a rotor of the alternator using a first switch having a first terminal electrically connected to an intermediate supply node, a second terminal electrically connected to the rotor, and a third terminal, wherein the excitation current provided to the rotor is a function of an excitation current control signal applied to the third terminal and a voltage at the intermediate supply node, so as to regulate an output voltage of the alternator, the excitation current control signal being generated by an alternator controller circuit that comprises an excitation current controller; detecting a fault condition of the first switch, via a supervision circuit, and generating a fault indication signal in response to said detecting and for as long as the fault condition persists; and responsive to the generated fault indication signal, continuously disconnecting a supply voltage from the intermediate supply node by opening a second switch electrically connected directly in series between the intermediate supply node and the supply voltage, and wherein the output voltage of the alternator provides the supply voltage.