Secure and dependable differential protection for electric power generators

What is claimed is: 1. A system for providing electrical power, comprising: an electric power generator with neutral-side terminals and power system side terminals, where the power system side terminals are in electrical communication with an electric power delivery system and the neutral-side terminals are in electrical communication with neutral; an intelligent electronic device (“IED”) comprising: a first set of conductors for communicating signals from the neutral-side terminals; a second set of conductors for communicating signals from the power system side terminals; an analog-to-digital converter in communication with the first and second sets of conductors for producing current signals therefrom; a differential element module in communication with the analog-to-digital converter, configured to issue an internal fault signal when the operating current exceeds a function of a restraining current value and the operating current exceeds the minimum of a first pickup value and a sum of  a second pickup value and  a scaled compensation addend comprising a sum of the current signals; a tripping module in communication with the differential element, configured to issue a tripping signal upon receipt of the internal fault signal; and, a circuit breaker in communication with the IED, configured to open upon receipt of the tripping signal from the IED. 2. A system for providing electrical power, comprising: an electric power generator with neutral-side terminals and power system side terminals, where the power system side terminals are in electrical communication with an electric power delivery system and the neutral-side terminals are in electrical communication with neutral; an intelligent electronic device (“IED”) comprising: a first set of conductors for communicating signals from the neutral-side terminals; a second set of conductors for communicating signals from the power system side terminals; an analog-to-digital converter in communication with the first and second sets of conductors for producing current signals therefrom; a differential element module in communication with the analog-to-digital converter, configured to issue an internal fault signal when an operating current from the current signals exceeds a function of a restraining current value from the current signals, and the operating current exceeds an adjusted pickup value; a tripping module in communication with the differential element, configured to issue a tripping signal upon receipt of the internal fault signal; and, a circuit breaker in communication with the IED, configured to open upon receipt of the tripping signal from the IED. 3. The system of claim 2 , wherein the differential element is further configured to calculate the function of the restraining current by scaling the restraining current with a high-security characteristic slope value. 4. The system of claim 2 , wherein the differential element is further configured to calculate an adjusted pickup value addend using the current signal values, and calculate the adjusted pickup value by summing an absolute value of the adjusted pickup value addend and a first pickup value. 5. The system of claim 4 , wherein the differential element is further configured to calculate the addend by compensating the current signals, and summing the compensated current signals. 6. The system of claim 5 , wherein the differential element is configured to compensate the current signals for differences between current transformers on the neutral-side terminals in communication with the first set of conductors, and current transformers on the power system side terminals in communication with the second set of conductors. 7. The system of claim 5 , wherein the differential element is configured to compensate the current signals for differences introduced by a step-up transformer between current transformers on the neutral-side terminals in communication with the first set of conductors, and current transformers on the power system side terminals in communication with the second set of conductors. 8. The system of claim 5 , further comprising filtering the current signals, wherein the filtering comprises cosine filtering. 9. The system of claim 4 , wherein the differential element is further configured to multiply the absolute value by a security scaling factor to calculate the adjusted pickup value addend. 10. The system of claim 2 , wherein the differential element is further configured to calculate an adjusted pickup value addend using the current signal values, and calculate the adjusted pickup value by summing an absolute value of the adjusted pickup value addend and a first pickup value, and select the minimum of the sum and a second pickup value as the adjusted pickup value. 11. The system of claim 10 , wherein the second pickup value comprises 1.25. 12. An intelligent electronic device (“IED”) for providing differential protection to an electric power generator, comprising: an analog-to-digital converter in electrical communication with conductors for communicating signals from a neutral side of an electrical generator and with conductors for communicating signals from a power system side of an electrical generator, configured to form current signals from the conductors; a differential element module in communication with the analog-to-digital converter, configured to issue an internal fault signal when an operating current value from the current signals exceeds a function of a restraining current value from the current signals, and the operating current value exceeds an adjusted pickup value; a tripping module in communication with the differential element, configured to issue a tripping signal upon receipt of the internal fault signal; and, a monitored equipment interface in communication with a circuit breaker, configured to signal the circuit breaker to open upon receipt of the tripping signal. 13. The system of claim 12 , wherein the differential element is further configured to calculate an adjusted pickup value addend using the current signal values, and calculate the adjusted pickup value by summing an absolute value of the adjusted pickup value addend and a first pickup value. 14. The system of claim 13 , wherein the differential element is further configured to calculate the addend by filtering the current signals, compensating the current signals, and summing the filtered compensated current signals. 15. The system of claim 14 , wherein the differential element is configured to compensate the current signals for differences between current transformers on the neutral side and current transformers on the power system side of the generator. 16. The system of claim 14 , wherein the differential element is configured to compensate the current signals for differences introduced by a step-up transformer to currents on the neutral side and on the power-system side of the generator. 17. The system of claim 12 , wherein the differential element is further configured to calculate an adjusted pickup value addend using the current signal values, and calculate the adjusted pickup value by summing an absolute value of the adjusted pickup value addend and a first pickup value, and select the minimum of the sum and the second pickup value as the adjusted pickup value. 18. A method for electric power generator differential protection, comprising the steps of: an intelligent electronic device (“IED”) in electrical communication with an electrical generator obtaining neutral-side and power system side current signals from th