Synchronous machine monitoring and determination of a loss-of-field event using time stamped electrical and mechanical data

What is claimed is: 1. An intelligent electronic device (“IED”) for monitoring a synchronous electrical power machine, comprising: a time input in communication with a common time reference; a mechanical data input in communication with the electrical power machine for providing a rotor position signal from the electrical power machine to the IED; an electrical data input for receiving electrical power machine electrical data, comprising: a field data input in communication with an exciter of the electrical power machine providing field current signals from the electrical power machine; and, a monitoring module in communication with the time input, the mechanical data input, and the electrical data input, and configured to: calculate rotor angles of the synchronous electrical power machine using the rotor position signal; calculate a transformation of the field current signals to a rotating reference frame using the rotor angles of the synchronous electrical power machine to form dq currents; during a successful operation of the electrical power machine without event, calculate a dq current baseline from the calculated dq currents during the successful operation; following the successful operation of the synchronous electrical power machine: calculate a present dq current of the synchronous electrical power machine using the rotor angles and the field current signals; compare the present dq current with the baseline; and signal an alarm when the present dq current differs from the baseline by more than a predetermined threshold. 2. An intelligent electronic device (“IED”) comprising: a time input in communication with a common time reference; a machine mechanical data input in communication with an electrical machine for providing a rotor position signal from the electrical machine; a field data input in communication with an exciter of the electrical machine providing field current signals from the electrical machine; a mechanical data module in communication with the time input and the machine mechanical data input for calculating rotor angles of a rotor of the electrical machine and time stamping the rotor angles using a time signal from the time input; a field data module in communication with the field data input and the time input for calculating a transformation of the field current signals to a rotating reference frame using the rotor angles of the electrical machine to form dq currents, and time stamping the dq currents using the time signal from the time input; and, a monitoring module in communication with the field data module and the mechanical data module, configured to determine a successful operation of the electrical machine as operation of the electrical machine without event for a predetermined time; calculate a dq current baseline from the calculated dq currents during the successful operation of the electrical machine; following the successful operation of the electrical machine: calculating a present dq current of the electrical machine from the rotor angles and the field current signals; comparing the present dq current against the calculated dq current baseline; and, when the calculated dq current is outside of the dq current baseline, determine a loss-of-field event of the electrical machine. 3. The intelligent electronic device of claim 2 , wherein the monitoring module is configured to determine whether the present dq current of the electric machine is outside of the dq current baseline by more than a predetermined margin. 4. The intelligent electronic device of claim 2 , wherein the monitoring module is further configured to store the dq current baseline. 5. The intelligent electronic device of claim 4 , wherein the monitoring module is further configured to compare a present dq current baseline with a past dq current baseline. 6. The intelligent electronic device of claim 5 , wherein the monitoring module is further configured to assert an alarm when a difference between the present dq current baseline and the past dq current baseline exceeds a predetermined threshold. 7. The intelligent electronic device of claim 2 , wherein the electrical machine comprises a synchronous generator. 8. The intelligent electronic device of claim 2 , wherein the electrical machine comprises a synchronous motor. 9. A method for monitoring an electrical power machine, comprising: an intelligent electronic device (“IED”) measuring a rotor position of the electrical power machine and calculating a rotor angle of the electrical power machine using the measured rotor position; the IED measuring field data from a field data input in communication with an exciter of the electrical power machine and calculating a field current of the electrical power machine using the field data; calculating a transformation of the field current to a rotating reference frame using the rotor angles of the electrical power machine during a successful operation of the electrical power machine without event to form a dq current baseline of the electrical power machine; calculating a transformation of the field current to a rotating reference frame using the rotor angles of the electrical power machine following the calculation of the dq current baseline to form a present dq current of the electrical power machine; and determining a loss-of-field event of the electrical power machine when a difference between the present dq current and the baseline dq current exceeds a predetermined margin. 10. The method of claim 9 , further comprising the step of comparing a present dq current baseline against a past dq current baseline. 11. The method of claim 10 , further comprising the step of asserting an alarm when a difference between the present dq current baseline and the past dq current baseline exceeds a predetermined threshold. 12. The method of claim 9 , wherein the electric power machine comprises a synchronous generator. 13. The method of claim 9 , wherein the electric power machine comprises a synchronous motor.