Self-calibrating device and method for in-phase and quadrature time skew and conjugation in a coherent transmitter

The invention claimed is: 1. A device comprising: a pilot tone generator configured to: combine a first pilot tone with a first frequency band of a digital data signal by modulating an amplitude of the first frequency band of the digital signal using the first pilot tone, and combine a second pilot tone with a second frequency band of the digital data signal by modulating an amplitude of the second frequency band of the digital signal using the second pilot tone, thereby generating a modified digital data signal; an electro-optic modulator (EOM) configured to generate an optical signal based on the modified digital data signal; a pilot tone detector configured to: receive the optical signal; generate a detector digital signal based on the optical signal; and detect a first pilot tone power and a second pilot tone power based on the detector digital signal; and a control unit configured to determine an IQ time skew between an in-phase component and a quadrature component of the optical signal based on a ratio between the first pilot tone power and second pilot tone power. 2. The device of claim 1 , further comprising a digital delay filter configured to: receive the modified digital data signal; set an IQ time skew bias based on control information from the control unit; and apply the IQ time skew bias to the modified digital data signal, wherein the control unit is further configured to: generate the control information based on the IQ time skew; and provide the control information to the digital delay filter. 3. The device of claim 2 , wherein: the first frequency band is a portion of digital signal spectrum above a predetermined frequency; and the second frequency band is a portion of digital signal spectrum below the predetermined frequency. 4. The device of claim 2 , wherein the control unit is further configured to perform IQ time-skew calibration by: providing skew sweep control information to the digital delay filter such that the digital delay filter sets the IQ time-skew bias equal to each of a plurality of IQ time-skew bias values; for each of the plurality of IQ time-skew bias values, calculating a respective power ratio between the first pilot tone power and second pilot tone power for the respective IQ time-skew bias value; calculating the IQ time skew based on the plurality of IQ time-skew bias values and the respective plurality of power ratios; and providing IQ skew calibration control information to the digital delay filter such that the digital delay filter sets the IQ skew bias to compensate for the IQ time skew. 5. The device of claim 4 , wherein the control unit is further configured to perform conjugation calibration by: determining a phase conjugation status of the optical signal based on: the plurality of IQ time-skew bias values and the respective plurality of power ratios; and phase bias information received from the EOM; and compensating for the phase conjugation status by setting a bias point of the EOM or inverting a polarity of the modified digital data signal. 6. The device of claim 5 , wherein the control unit is further configured to perform IQ time-skew calibration and conjugation calibration during a power-up phase of the device. 7. The device of claim 4 , wherein calculating the IQ time skew based on the plurality of IQ time-skew bias values and the respective plurality of power ratios comprises: calculating a linear interpolation of the plurality of IQ time-skew bias values and the respective plurality of power ratios; identifying a balance point on the linear interpolation corresponding to a power ratio value of 1:1; and setting the IQ time skew equal to an IQ time skew bias value corresponding to the balance point. 8. The device of claim 5 , wherein determining a phase conjugation status of the optical signal comprises: calculating a linear interpolation of the plurality of IQ time-skew bias values and the respective plurality of power ratios; identifying a positive or negative sign of a slope of the linear interpolation; and determining that the optical signal is conjugated based on the sign of the slope of the linear interpolation and the phase bias information. 9. The device of claim 4 , wherein: the first pilot tone has a modulation frequency that is different from a modulation frequency of the second pilot tone; and the pilot tone generator is configured to modulate the power of the first frequency band with the first pilot tone while modulating the power of the second frequency band with the second pilot tone. 10. The device of claim 4 , wherein: the first pilot tone and second pilot tone are both a single pilot tone having a single pilot tone modulation frequency; and the pilot tone generator is configured to alternate over time between: modulating the power of the first frequency band with the single pilot tone; and modulating the power of the second frequency band with the single pilot tone. 11. The device of claim 1 , wherein the pilot tone generator is further configured to: apply a fast Fourier transform to the digital data signal to generate a frequency-domain digital data signal; apply a digital signal processing unit to the frequency-domain digital data signal to obtain the first frequency band signal in a frequency domain and the second frequency band signal in the frequency domain; apply an inverse fast Fourier transform to the first frequency band signal in the frequency domain and the second frequency band signal in the frequency domain to obtain the first frequency band signal in a time domain and the second frequency band signal in the time domain; wherein modulating the amplitude of the first frequency band signal using the first pilot tone is performed in the time domain; and wherein modulating the amplitude of the second frequency band signal using the second pilot tone is performed in the time domain. 12. The device of claim 1 , wherein modulating the amplitude of first frequency band signal and modulating the amplitude of the second frequency band signal is performed using a modulation index between 1% and 3%. 13. The device of claim 12 , wherein the first pilot tone and second pilot tone each have a respective modulation frequency between 100 KHz and 100 MHz. 14. The device of claim 1 , wherein the electro-optic modulator comprises a dual-polarization IQ Mach-Zehnder modulator. 15. A method, comprising: combining a first pilot tone with a first frequency band of a digital data signal by modulating an amplitude of the first frequency band of the digital signal using the first pilot tone, and combining a second pilot tone with a second frequency band of the digital data signal by modulating an amplitude of the second frequency band of the digital signal using the second pilot tone, thereby generating a modified digital data signal; generating an optical signal based on the modified digital data signal; generating a detector digital signal based on the optical signal; detecting a first pilot tone power and a second pilot tone power based on the detector digital signal; and using a ratio between the first pilot tone power and second pilot tone power to determine an IQ time skew between an in-phase component and a quadrature component of the optical signal. 16. The method of claim 15 , further comprising performing IQ time-skew calibration by: setting an IQ time-skew bias equal to each of a plurality of IQ time-skew bias values; for each of the plurality of IQ time-skew bias values: applying the IQ time-skew bias to the digital data signal; and cal