Systems and methods for routing sampled values upon loss of primary measurement equipment

What is claimed is: 1. A communication system for dynamically routing power system signals from measurement devices to intelligent electronic devices (IEDs), comprising: a sampled values (SV) communicator that includes: a first communication port to receive power system signals corresponding to measurements made by a first measurement device within a first portion of an electric power delivery system; a second communication port to output the power system signals from the first measurement device to a first IED configured to monitor the first portion of the electric power delivery system using received power system signals; a third communication port to receive power system signals corresponding to measurements made by a second measurement device within a second portion of the electric power delivery system; a fourth communication port to output the power systems signals from the second measurement device to a second IED configured to monitor the second portion of the electric power delivery system using received power system signals; a detection subsystem to detect that the first communication port has failed to receive the power system signals; and a rerouting subsystem to dynamically route the power system signals received at the third communication port from the second measurement device to the first IED via the second communication port and the second IED via the fourth communication port. 2. The system of claim 1 , wherein the first measurement device comprises a first current transformer (CT) and the second measurement device comprises a second CT. 3. The system of claim 1 , wherein the detection subsystem is configured to receive a notification of failure from an external monitoring device. 4. The system of claim 1 , wherein the first communication port comprises a fiber optic port and the detection subsystem is configured to detect that the first communication port has failed to receive the power system signals based on a loss of fiber optic signal. 5. The system of claim 4 , wherein the detection subsystem is configured to detect that the loss of fiber optic signal between sampled values from the first measurement device, such that the rerouting subsystem can dynamically route the power system signals from the third communication port to the first IED without any lost sampled values. 6. A system for providing electric power system signals to intelligent electronic devices (IEDs), comprising: a first measurement device to obtain measurement data from a first portion of the electric power delivery system; a second measurement device to obtain measurement data from a second portion of the electric power delivery system; a first IED to monitor the first portion of the electric power delivery system based on measurement data associated with the first portion of the electric power delivery system; a second IED to monitor the second portion of the electric power delivery system based on measurement data associated with the second portion of the electric power delivery system; a supervisory coordination device to determine a state of coordination of the first and second portions of the electric power delivery system as either a coordinated state with the first and second measurement devices capturing coordinated measurement data, or an uncoordinated state with the first and second measurement devices capturing uncoordinated measurement data; and a sampled values (SV) communicator to: in a default state, route measurement data from the first measurement device to the first IED, and route measurement data from the second measurement device to the second IED, and upon failure to receive measurement data from the first measurement device when the first and second portions are in a coordinated state, route measurement data from the second measurement device to the first IED and to the second IED. 7. The system of claim 6 , wherein the supervisory coordination device is configured to determine that the first and second portions of the electric power system are in a coordinated state based on a determination that a switch connecting the first and second portions of the electric power system is closed. 8. The system of claim 6 , wherein the first measurement device comprises: a first sensor to capture measurement data from the first portion of the electric power system; and a first merging unit to create digitized electrical signals of the measurement data from the first sensor for delivery to the communication system; and wherein the second measurement device comprises: a second sensor to capture measurement data from the second portion of the electric power system; and a second merging unit to create digitized electrical signals of the measurement data from the second sensor for delivery to the communication system. 9. The system of claim 8 , wherein each of the first and second sensors comprises at least one of a: current transformer (CT) and a potential transformer (PT). 10. The system of claim 6 , wherein the first measurement device comprises a first optical current transformer and the second measurement device comprises a second optical current transformer. 11. The system of claim 6 , wherein the first and second portions of the electric power delivery system are capturing coordinated power measurement data when the measurement data is expected to be substantially identical based on modeling of system conditions. 12. The system of claim 6 , wherein the SV communicator comprises a communication switch in communication with the first and second merging units and the first and second IEDs. 13. The system of claim 6 , wherein the SV communicator comprises: a first dynamic networking SV communicator in communication with the first merging unit and the first and second IEDs; and a second dynamic networking SV communicator in communication with the second merging unit and the first and second IEDs. 14. The system of claim 13 , wherein the first dynamic networking SV communicator is also in communication with the second merging unit; and the second dynamic networking SV communicator is also in communication with the first merging unit. 15. The system of claim 6 , wherein the SV communicator identifies a failure to receive measurement data from the first measurement device based on a loss of a fiber optic communication signal. 16. A method of providing electric power system signals from merging units to intelligent electronic devices (IEDs), comprising: obtaining electrical signals from a first portion of an electric power delivery system using a first merging unit; creating digitized electrical signals from the obtained electrical signals from the first portion of the electric power delivery system by the first merging unit; communicating the digitized electrical signals from the first portion of the electric power delivery system to a communication system; obtaining electrical signals from a second portion of the electric power delivery system using a second merging unit; creating digitized electrical signals from the second portion of the electric power delivery system by the second merging unit; communicating the digitized electrical signals from the obtained electrical signals from the second portion of the electric power delivery system to the communication system; communicating the digitized electrical signals from the first portion of the electrical power system to a first IED by the communication system; communicating the digitized electrical signals from the second portion of the electrical power system to a second IED by the communication system; the commu