Current sensor output converter for circuit breakers that are configured for Rogowski coils

The invention claimed is: 1. An electrical system comprising: a first power source; a first circuit breaker that is electrically connected to an output of the first power source; a first trip unit for the first circuit breaker; a first current transformer that is positioned to detect current passing through a neutral line that extends from the first power source; and a first converter circuit that is positioned to: receive a signal from an output of the first current transformer, convert the received signal to a first voltage signal, and send the first voltage signal to the first trip unit, wherein during operation the first voltage signal will have a voltage that is proportional to a time rate of change of the received signal, wherein the system is a main-tie-main system that also comprises: a second power source; a second circuit breaker that is electrically connected to an output of the second power source; a second trip unit for the second circuit breaker; a second current transformer that is positioned to detect current passing through a neutral line that extends from the second power source, and that has an output that is electrically connected to the second trip unit; a second converter circuit that is positioned to: receive a signal from the output of the second current transformer, convert the signal received from the output of the second current transformer to a second voltage signal, and send the second voltage signal to the second trip unit; and a third circuit breaker that is electrically connected to both the first power source and the second power source. 2. The system of claim 1 , wherein the first converter circuit comprises: an input component that is electrically connected to receive the first signal from the first current transformer; a burden resistor that is electrically connected across a coil of the input component; and a passive differentiator that is electrically connected across the burden resistor, wherein: the passive differentiator comprises a resistor and a capacitor, and the output of the current converter is configured to deliver the first voltage signal from the passive differentiator during operation. 3. The system of claim 2 , wherein: the input component of the first converter circuit comprises a current transformer; and the coil across which the burden resistor is electrically connected is a secondary winding of the current transformer. 4. The system of claim 2 , wherein a resistance value of the resistor of the passive differentiator is substantially less than an impedance value of the capacitor of the passive differentiator at a given operating frequency. 5. The system of claim 2 , wherein the first converter circuit further comprises an inductor that has one end that is electrically connected to a circuit reference and serves to add phase shift lost at a high end of an operating range. 6. The system of claim 2 , wherein the first converter circuit does not require a power source to convert the deliver, from the passive differentiator during operation, the converted output voltage. 7. The system of claim 1 , wherein: the neutral lines that extend from the first power source and the second power source are electrically connected to each other; and each of the first and second converter circuits is electrically connected to each of the neutral lines. 8. A converter circuit for receiving signals from one or more current transformers and outputting a signal to a circuit breaker trip unit, the converter circuit comprising: an input component that is electrically connected to receive an output signal from each of one or more current transformers of a circuit breaker; a burden resistor that is electrically connected across a coil of the input component; a passive differentiator that is electrically connected across the burden resistor, wherein the passive differentiator comprises a resistor and a capacitor; and an output that is configured to deliver, from the passive differentiator during operation, a converted output voltage that is proportional to a time rate of change of a signal that is received by the input component, such that the converted output voltage does not need to be processed by an integrated circuit in order for the trip unit to make a determination to output a trip signal. 9. The converter circuit of claim 8 , wherein the input component comprises a current transformer, and the coil of the input component across which the burden resistor is electrically connected comprises a secondary coil of the current transformer. 10. The converter circuit of claim 8 , wherein a resistance value of the resistor of the passive differentiator is substantially less than an impedance value of the capacitor of the passive differentiator at a given operating frequency. 11. The converter circuit of claim 8 , further comprising an inductor that has one end that is electrically connected to a circuit reference and serves to add phase shift lost at a high end of an operating range of the converter circuit. 12. The converter circuit of claim 8 , wherein: the circuit breaker is a component of a main-tie-main system; the input component is electrically connected to a plurality of current transformers of the main-tie-main system; and each of the current transformers of the main-tie-main system is configured to detect current output by one or more neutral lines of a corresponding source that is electrically connected to the main-tie-main system. 13. The converter circuit of claim 8 , wherein the converter circuit does not require a power source to deliver, from the passive differentiator during operation, the converted output voltage. 14. An electrical system having a main-tie-main configuration, the system comprising: a first power source; a first circuit breaker that is electrically connected to an output of the first power source; a first trip unit for the first circuit breaker; a first current transformer that is positioned to detect current passing through a neutral line that extends from the first power source; a second power source; a second circuit breaker that is electrically connected to an output of the second power source; a second trip unit for the second circuit breaker; a second current transformer that is positioned to detect current passing through a neutral line that extends from the second power source, and that has an output that is electrically connected to the second trip unit; a third circuit breaker that is electrically connected to both the first power source and the second power source; a first converter circuit that is positioned to: receive signals from the first and second current transformers, sum and convert the signals received from the output of the first and second current transformers to a first voltage signal, and send the first voltage signal to the first trip unit, wherein during operation the first voltage signal will have a rate of change that is proportional to a rate of change of the signals received by the first converter circuit; and a second converter circuit that is positioned to: receive signals from the first and second current transformers, sum and convert the signals received from the output of the first and second current transformers to a second voltage signal, and send the second higher voltage signal to the second trip unit, wherein during operation the second voltage signal will have a rate of change that is proportional to a rate of change of the signals received by the second converter circuit. 15. The system of claim 14 , wherein each of the conve