Optical signal transmitter and optical signal encoder using constant modulus formats, and method for generating modulation codes

We claim: 1. An encoder for generating an optical data code from a symbol comprising: a processor to perform a symbol mapping program and an encoding program; a memory, in connection with the processor, to store the symbol mapping and encoding programs, wherein the symbol mapping program causes the processor to perform: providing a first constellation format having first and second amplitude rings with circular grids corresponding to phase angles; providing a second constellation format having the first and second amplitude rings with the circular grids corresponding to the phase angles; applying a first part of the symbol to one of the first and second constellation formats to represent the first part of the symbol by one of the first and second amplitude rings with one of the circular grids; applying a second part of the symbol to another one of the first and second constellation formats to represent the second part of the symbol by one of the first and second amplitude rings with one of the circular grids; and providing pairs of superchannels arranged according to time slots, wherein each of the superchannels includes subcarriers allocated to subchannel numbers, wherein the first and second parts of the symbol are allocated to a pair of the subcarriers, wherein a sum of powers of the pair of the subcarriers is chosen so as to become approximately a predetermined value, wherein each of the superchannels is uniformly divided by the subcarriers corresponding to subcarrier symbol rates, and wherein the encode program causes the processor to perform: encoding the first part of the symbol into a first subset of the optical data code using the one of the first and second amplitude rings with the one of the circular grids according to the one of the first and second constellation formats; and encoding the second part of the symbol into a second subset of the optical data code using the one of the first and second amplitude rings with the one of the circular grids according to the other one of the first and second constellation formats. 2. The encoder of claim 1 , wherein each pair of the superchannels consists of a first part and a second part, wherein the first part of the pair is allocated to the first constellation format and the second part of the pair is allocated to the second constellation format. 3. The encoder of claim 2 , wherein the first part of the symbol is allocated to the first subchannel number of the first part of the pair, wherein the second part of the symbol is allocated to the second subchannel number of the second part of the pair, wherein the first subchannel number is identical to the second subchannel number. 4. The encoder of claim 1 , wherein a ratio of radii of the first and second amplitude rings is set in a range between 0.5 and 0.8. 5. The encoder of claim 1 , wherein the first and second parts of the symbol are arranged in at least one of the superchannels. 6. The encoder of claim 1 , wherein each of the subcarrier symbol rates is in a range between 1 Giga baud-rate (GBd) and 100 GBd. 7. The encoder of claim 1 , wherein the first and second parts of the symbol are arranged into an identical one of the superchannels, wherein the first and second parts of the symbol are arranged to two subcarriers of the identical one of the superchannels such that the two subcarriers are apart via a predetermined number of the subcarriers. 8. The encoder of claim 7 , wherein the predetermined number is zero. 9. The encoder of claim 1 , wherein the first and second parts of the symbol are respectively allocated to a first subchannel number and a second subchannel number of consecutive first and second superchannels, wherein both of the first and second superchannels belong to one of the first and second parts of the pair, wherein the first subchannel number is identical to the second subchannel number. 10. The encoder of claim 1 , wherein when the first constellation format is an X-polarization constellation and the second constellation format is a Y-polarization constellation, wherein when the first constellation format is the Y-polarization constellation and the second constellation format is the X-polarization constellation. 11. The encoder of claim 10 , wherein a total number of the subcarriers per polarization and a time slot is one. 12. The encoder of claim 1 , wherein the first and second constellation formats are represented by a 6 bits-4-dimensional coded modulation format. 13. The encoder of claim 1 , wherein the first and second constellation formats are represented by a 7 bits-4-dimensional coded modulation format. 14. The encoder of claim 1 , wherein the first and second constellation formats are represented by multiple four-dimensional constant modulus formats. 15. The encode of claim 1 , wherein the mapping of the first and second constellation formats is reconfigurable and can be selected depending on the fiber transmission characteristics. 16. An optical transmitter comprising: an encoder device of claim 1 configured to generate and transmit first and second modulation signals; a continuous wave (CW) optical source configured to transmit a CW optical signal; a polarization beam splitter configured to split the CW optical signal of the CW optical source into first and second parts of the CW optical signal; a first modulator connected to the encoder device, wherein the first modulator receives and modulates the first part of the CW optical signal to generate a first modulated optical carrier signal according to the first modulation signal; a second modulator connected to the encoder device, wherein the second modulator receives and modulates the second part of the CW optical signal to generate a second modulated optical carrier signal according to the second modulation signal; and a beam combiner configured to combine the first and second modulated optical carrier signals to generate and transmit a modulated optical carrier signal. 17. The optical transmitter of claim 16 , wherein each pair of the superchannels consists of a first part and a second part, wherein the first part of the pair is allocated to the first constellation format and the second part of the pair is allocated to the second constellation format. 18. The optical transmitter of claim 17 , wherein the first part of the symbol is allocated to the first subchannel number of the first part of the pair, wherein the second part of the symbol is allocated to the second subchannel number of the second part of the pair, wherein the first subchannel number is identical to the second subchannel number. 19. The optical transmitter of claim 16 , wherein the first and second parts of the symbol are arranged into an identical one of the superchannels, wherein the first and second parts of the symbol are arranged to two subcarriers of the identical one of the superchannels such that the two subcarriers are apart via a predetermined number of the subcarriers. 20. The optical transmitter of claim 16 , wherein the first part of the symbol is allocated to the first subchannel number of the first part of the pair, wherein the second part of the symbol is allocated to the second subchannel number of the second part of the pair, wherein the first subchannel number is identical to the second subchannel number. 21. The optical transmitter of claim 16 , wherein when the first constellation format is based on an X-polarization constellation and the second constellation format is based on a Y-polarization constellation, where