Method and apparatus for characterization and compensation of optical impairments in InP-based optical transmitter

What is claimed is: 1. A method for characterizing and compensating for optical impairments in an optical transmitter, the method comprising: a) operating an optical transmitter comprising a first parent Mach-Zehnder (MZ) modulator and a second parent MZ modulator, wherein each of the first and second parent MZ modulators comprises a plurality of child MZ modulators; b) biasing each of the plurality of child MZ modulators in the first and second parent MZ modulators at respective initial operating points; c) generating an electro-optic RF transfer function for each of the plurality of child MZ modulators by measuring a plurality of optical output powers of the optical transmitter while sweeping characterizing RF input drive power levels applied to each of the plurality of child MZ modulators; d) determining curve fitting parameters for each of the plurality of electro-optic RF transfer functions; e) determining operating points of each of the plurality of child MZ modulators using the curve fitting parameters; f) determining a power imbalance of at least two of the plurality of child MZ modulators at a select operating point; and g) determining control set points for a first and second modulator drive amplifier electrically connected to a respective one of the at least two of the plurality of child MZ modulators that compensate for at least some of the power imbalance. 2. The method of characterizing and compensating of claim 1 wherein the plurality of child MZ modulators comprise InP MZ modulators. 3. The method of characterizing and compensating of claim 1 wherein the optical transmitter operates at a particular wavelength. 4. The method of characterizing and compensating of claim 1 wherein the optical transmitter operates over a range of wavelengths. 5. The method of characterizing and compensating of claim 4 wherein the control set points are determined over the range of wavelengths. 6. The method of characterizing and compensating of claim 4 wherein the range of wavelengths comprises a range of wavelengths in the C-band range. 7. The method of characterizing and compensating of claim 6 wherein the range of wavelengths comprises each wavelength on the ITU grid across the full C-band range. 8. The method of characterizing and compensating of claim 1 wherein the first parent MZ modulator generates a modulated optical beam having a first polarization and the second parent MZ modulator generates a modulated optical beam having a second polarization. 9. The method of characterizing and compensating of claim 1 wherein the biasing each of the plurality of child MZ modulators at the initial operating point comprises biasing the plurality of child MZ modulators at a minimum transmission level. 10. The method of characterizing and compensating of claim 1 wherein the biasing each of the plurality of child MZ modulators at the initial operating point comprises biasing the plurality of child MZ modulators at a bias that results in an optical output power that is less than −45 dBm. 11. The method of characterizing and compensating of claim 1 wherein the characterizing RF input drive power is performed at a particular RF frequency. 12. The method of characterizing and compensating of claim 11 wherein the particular RF frequency is in a range of 500 MHz and 3 GHz. 13. The method of characterizing and compensating of claim 11 wherein the particular RF frequency is approximately 1 GHz. 14. The method of characterizing and compensating of claim 1 wherein the sweeping the characterizing RF input drive power of each of the plurality of modulators comprises sweeping the characterizing RF input drive power of each of the plurality of child MZ modulators sequentially. 15. The method of characterizing and compensating of claim 1 wherein the sweeping the characterizing RF input drive power comprises sweeping characterizing RF input drive power of each of the plurality of child MZ modulators through a respective V π of the child MZ modulators. 16. The method of characterizing and compensating of claim 1 wherein the sweeping the characterizing RF input drive power comprises varying an output power of an external RF signal generator coupled to an RF input of each of the plurality of child MZ modulators. 17. The method of characterizing and compensating of claim 16 wherein the output power of the external RF signal generator is varied in a range of −15 dBm to +6 dBm. 18. The method of characterizing and compensating of claim 1 wherein the measuring the plurality of optical output powers of the optical transmitter while sweeping characterizing RF input drive power levels applied to each of the plurality of child MZ modulators comprises reading swept characterizing RF input drive power from an RF peak detector. 19. The method of characterizing and compensating of claim 18 further comprising calibrating the RF peak detector by measuring the response of the RF peak detector at three or more applied input voltages. 20. The method of characterizing and compensating of claim 1 wherein the determining the control set points is performed in the field. 21. The method of characterizing and compensating of claim 1 wherein the determining curve fitting parameters for each of the plurality of electro-optic RF transfer functions comprises performing a linear curve fit. 22. The method of characterizing and compensating of claim 1 wherein the determining curve fitting parameters for each of the plurality of electro-optic RF transfer functions comprises performing a polynomial curve fit. 23. The method of characterizing and compensating of claim 1 wherein the determining curve fitting parameters for each of the plurality of electro-optic RF transfer functions comprises performing an inverse cosine curve fit. 24. The method of characterizing and compensating of claim 1 wherein the select operating point is such that the optical transmitter produces a DP-QPSK modulation format. 25. The method of characterizing and compensating of claim 1 wherein the select operating point is such that the optical transmitter produces a DP-16QAM modulation format. 26. The method of characterizing and compensating of claim 1 further comprising performing automatic gain control using the control set points of the modulator drive amplifiers to compensate power imbalances in the optical transmitter. 27. The method of characterizing and compensating of claim 26 wherein the optical transmitter operates over a range of wavelengths. 28. The method of characterizing and compensating of claim 27 wherein the control set points are determined over the range of wavelengths. 29. The method of characterizing and compensating of claim 28 wherein the range of wavelengths comprises a range of wavelengths in the C-band range. 30. The method of characterizing and compensating of claim 28 wherein the range of wavelengths comprises each wavelength on the ITU grid. 31. A method of characterizing and compensating for optical impairments in an InP-based optical transmitter, the method comprising: a) operating an optical transmitter comprising a first and a second parent MZ modulator, wherein each of the first and second parent MZ modulators comprise a plurality of child MZ modulators; b) biasing each of the plurality child MZ modulators in each of the first