Feeder fiber and central office redundancy

What is claimed is: 1. An optical network comprising: a first carrier office (CO) configured to transmit first and second optical signals; a second CO configured to transmit a third optical signal, the third optical signal being the same as the first optical signal; a first feeder fiber optically coupled to the first CO; a second feeder fiber optically coupled to the first CO; a third feeder fiber optically coupled to the second CO; a first remote node (RN) optically coupled to the first feeder fiber and the third feeder fiber; and a controller in communication with the first and second COs, the controller configured to perform operations comprising: instructing the first CO to transmit the first optical signal to the first RN along the first feeder fiber; determining whether the first RN receives the first optical signal; and when the first RN fails to receive the first optical signal, instructing the second CO to transmit the third optical signal to the first RN along the third feeder fiber, wherein the first CO comprises: a first optical line terminal (OLT) configured to transmit the first and second optical signals; a first transmit-erbium-doped fiber amplifier (EDFA) optically coupled to the first OLT and the first feeder fiber, the first transmit-EDFA operable between a respective enabled state and a respective disabled state, the enabled state of the first transmit-EDFA configured to allow the first optical signal transmitted from the first OLT to pass through the first transmit-EDFA to the first RN, the disabled state of the first transmit-EDFA configured to substantially inhibit the passing of the first optical signal from the first OLT through the first transmit-EDFA to the first RN; a second transmit-EDFA optically coupled to the first OLT and the second feeder fiber, the second feeder fiber optically coupled to a second RN, the second transmit-EDFA operable between a respective enabled state and a respective disabled state, the enabled state of the second transmit-EDFA configured to allow the second optical signal transmitted from the first OLT to pass through the second transmit-EDFA to the second RN, the disabled state of the second transmit-EDFA configured to substantially inhibit the passing of the second optical signal from the first OLT through the second transmit-EDFA to the second RN; a first receive-EDFA optically coupled to the first OLT and the first feeder fiber, the first receive-EDFA operable between a respective enabled state and a respective disabled state, the enabled state of the first receive-EDFA configured to allow a fourth optical signal from the first RN to pass through the first receive-EDFA to the first OLT, the disabled state of the first receive-EDFA configured to substantially inhibit the passing of the fourth optical signal from the first RN through the first receive-EDFA to the first OLT; and a second receive-EDFA optically coupled to the first OLT and the second feeder fiber, the second receive-EDFA operable between a respective enabled state and a respective disabled state, the enabled state of the second receive-EDFA configured to allow a fifth optical signal from the second RN to pass through the second receive-EDFA to the first OLT, the disabled state of the second receive-EDFA configured to substantially inhibit the passing of the fifth optical signal from the second RN through the second receive-EDFA to the first OLT. 2. The optical network of claim 1 , wherein the second CO comprises: a second optical line terminal (OLT) configured to transmit the third optical signal; a third transmit-EDFA optically coupled to the second OLT and the third feeder fiber, the second transmit-EDFA operable between a respective enabled state and a respective disabled state, the enabled state of the third transmit-EDFA configured to allow the third optical signal transmitted from the second OLT to pass through the second transmit-EDFA to the first RN, the disabled state of the third transmit-EDFA configured to substantially inhibit the passing of the third optical signal from the second OLT through the third transmit-EDFA to the first RN. 3. The optical network of claim 2 , wherein the operations further comprise: receiving a remote node status indicating whether the first RN is receiving the first optical signal from the first CO; and when the remote node status indicates that the first RN is not receiving the first optical signal from the first CO, instructing the third transmit-EDFA to be in the enabled state. 4. The optical network of claim 3 , wherein the operations further comprise, when the remote node status indicates that the first RN is receiving the first optical signal from the first CO, instructing the third transmit-EDFA to be in the disabled state. 5. The optical network of claim 1 , wherein the first OLT comprises a laser array configured to transmit multiple optical signals. 6. The optical network of claim 1 , wherein the first OLT comprises two or more transceivers each configured to transmit a corresponding downstream optical signal at a corresponding target wavelength. 7. The optical network of claim 1 , wherein the first CO further comprises: a multiplexer optically coupled to the first OLT and configured to multiplex the first and second optical signals into a multiplexed signal; and a splitter optically coupled to the multiplexer and the first and second transmit-EDFAs, the splitter configured to: split the multiplexed signal received from the multiplexer into first and second split-multiplexed signals; route the first split-multiplexed signal to the first transmit-EDFA; and route the second split-multiplexed signal to the second transmit-EDFA. 8. The optical network of claim 7 , wherein the first CO further comprises: a first band multiplexer optically coupled to the first transmit-EDFA and the first feeder fiber, the first band multiplexer configured to receive the first split-multiplexed signal from the first transmit-EDFA and pass the first split-multiplexed signal as a downstream component of the first optical signal to the first RN; and a second band multiplexer optically coupled to the second transmit-EDFA and the second feeder fiber, the second band multiplexer configured to receive the second split-multiplexed signal from the second transmit-EDFA and pass the second split-multiplexed signal as a downstream component of the second optical signal to the second RN. 9. The optical network of claim 1 , wherein the controller is in communication with the first and second transmit-EDFAs, and wherein the controller is configured to: receive a remote node status indicating whether the second RN is receiving optical signals from another carrier office; and when the remote node status indicates that the second RN is not receiving optical signals from the other carrier office, instruct the second transmit-EDFA to be in the enabled state. 10. The optical network of claim 9 , wherein the controller is further configured to, when the remote node status indicates that the second RN is receiving optical signals from the other carrier office, instructing the second transmit-EDFA to be in the disabled state. 11. The optical network of claim 1 , wherein the first CO further comprises: a first band multiplexer optically coupled to the first receive-EDFA and the first feeder fiber, the first band multiplexer configured to demultiplex out the fourth optical signal from the first optical signal and pass the fourth optical signal to the first receive-EDFA; and a second band multiplexer optically coupled to the second receive-EDFA and the second feeder fiber, the second band multiplexer configured to demultiplex out the fifth