Parity frame

What is claimed is: 1. A method of forward error correction (FEC) in an optical communications system, the method comprising: in a receiver signal processor of an optical receiver of the optical communications system decoding a super-frame from a received optical signal in accordance with a first FEC scheme to generate a first set of FEC-decoded frames having no residual errors and a second set of FEC-decoded frames, each of the FEC-decoded frames of the second set having plural residual errors, wherein the residual errors are clustered as a result of an error correlation characteristic of the first FEC scheme; and processing all of the FEC-decoded frames of the first set with a second FEC scheme to correct the plural clustered residual errors in one or more FEC-decoded frames of the second set. 2. The method as recited in claim 1 , wherein processing all of the FEC-decoded frames of the first set with the second FEC scheme comprises calculating a local parity frame from all of the FEC-decoded frames of the first set. 3. The method as recited in claim 2 , further comprising correcting the plural clustered residual errors in one of the FEC-decoded frames of the second set by replacing that one of the FEC-decoded frames of the second set with the local parity frame. 4. The method as recited in claim 2 , wherein calculating the local parity frame comprises accumulating a bit-wise soft metric. 5. The method as recited in claim 1 , the method further comprising: stopping the decoding of the super-frame when a number of FEC-decoded frames in the first set is sufficient that any remaining frames of the super-frame can be reconstructed using the second FEC scheme; and reconstructing the remaining frames using the second FEC scheme. 6. An optical receiver comprising: a receiver signal processor configured to decode a super-frame from a received optical signal in accordance with a first FEC scheme to generate a first set of FEC-decoded frames having no residual errors and a second set of FEC-decoded frames, each of the FEC-decoded frames of the second set having plural residual errors, wherein the residual errors are clustered as a result of an error correlation characteristic of the first FEC scheme; and to process all of the FEC-decoded frames of the first set with a second FEC scheme to correct the plural clustered residual errors in one or more FEC-decoded frames of the second set. 7. The optical receiver as recited in claim 6 , wherein the receiver signal processor is configured to calculate a local parity frame from all of the FEC-decoded frames of the first set. 8. The optical receiver as recited in claim 7 , wherein the receiver signal processor is configured to correct the plural clustered residual errors in one of the FEC-decoded frames of the second set by replacing that one of the FEC-decoded frames of the second set with the local parity frame. 9. The optical receiver as recited in claim 7 , wherein the receiver signal processor is configured to calculate the local parity frame by accumulating a bit-wise soft metric. 10. The optical receiver as recited in claim 6 , wherein the receiver signal processor is configured to stop the decoding of the super-frame when a number of FEC-decoded frames in the first set is sufficient that any remaining frames of the super-frame can be reconstructed using the second FEC scheme; and to reconstruct the remaining frames using the second FEC scheme. 11. An optical receiver comprising: a receiver signal processor configured to decode a super-frame from a received optical signal in accordance with a first FEC scheme to generate a set of FEC-decoded frames having residual errors, wherein the residual errors are clustered as a result of an error correlation characteristic of the first FEC scheme; and to use a second FEC scheme to correct the clustered residual errors, wherein the second FEC scheme is selected based on the error correlation characteristic of the first FEC scheme and is designed to correct the clustered residual errors, wherein the super-frame comprises FEC-encoded data frames and a single parity frame, the FEC-encoded data frames having been encoded in a transmitter signal processor of an optical transmitter from two or more data frames in accordance with the first FEC scheme, and the single parity frame having been computed in the transmitter signal processor across the two or more data frames in accordance with the second FEC scheme. 12. The optical receiver as recited in claim 11 , wherein the receiver signal processor is configured to accumulate a bit-wise soft metric for use according to the second FEC scheme to correct the clustered residual errors. 13. The optical receiver as recited in claim 11 , wherein the receiver signal processor is configured to use the single parity frame as decoded from the super-frame for use according to the second FEC scheme to correct the clustered residual errors. 14. The optical receiver as recited in claim 13 , wherein the receiver signal processor is configured to replace an errored FEC-decoded frame with the single parity frame as decoded from the super-frame. 15. The optical receiver as recited in claim 11 , wherein the receiver signal processor is configured to calculate a local parity frame from the set of FEC-decoded frames for use according to the second FEC scheme to correct the clustered residual errors. 16. The optical receiver as recited in claim 15 , wherein the local parity frame is calculated only from FEC-decoded frames in which there are no residual errors. 17. The optical receiver as recited in claim 16 , wherein the receiver signal processor is configured to replace an errored FEC-decoded frame with the local parity frame. 18. The optical receiver as recited in claim 15 , wherein calculating the local parity frame comprises accumulating a bit-wise soft metric. 19. The optical receiver as recited in claim 11 , the receiver signal processor configured to stop the decoding of the super-frame when a number of FEC decoded frames in which there are no residual errors is sufficient that any remaining frames of the super-frame can be reconstructed using the second FEC scheme; and to reconstruct the remaining frames using the second FEC scheme.