Photonic analog-to-digital converter (pADC) with photonic phase correction

I claim: 1. A photonic analog-digital converter (pADC), comprising: a passive remote sampler (PRS) configured to: receive at least one radio frequency (RF) signal of interest; and modulate at least one optical pulse according to the received RF signal of interest; a base unit having a sending side and a receiving side, the sending side and the receiving side both optically coupled to the PRS, the receiving side configured to: measure a phase drift associated with the PRS by sending a continuous-wave (CW) optical signal through the PRS in a reverse optical path; and receive the at least one modulated optical pulse via the PRS; the sending side comprising: an optical pulse source configured to transmit the optical pulse through the PRS in a forward optical path; and at least one photodiode configured to convert the CW optical signal into an electrical signal indicative of the phase drift; and the receiving side configured to: receive the electrical signal from the sending side; and correct the phase drift associated with the at least one modulated optical pulse based on the electrical signal. 2. The pADC of claim 1 , wherein: the PRS is configured to modulate the CW optical signal according to the received RF signal of interest; and the at least one photodiode is configured to filter a phase-error signal corresponding to the phase drift from the electrical signal converted from the CW optical signal. 3. The pADC of claim 2 , wherein the at least one photodiode is configured to filter the phase-error signal from the electrical signal based on a frequency disparity between the phase-error signal and the RF signal of interest. 4. The pADC of claim 1 , wherein the base unit includes at least one wavelength division multiplexer (WDM) configured to separate the optical pulse and the CW optical signal based on a frequency disparity between the optical pulse and the CW optical signal. 5. The pADC of claim 4 , wherein the frequency disparity between the optical pulse and the CW optical signal is not less than 10 nm. 6. The pADC of claim 1 , wherein the PRS includes: a first coupler configured to split the optical pulse into a signal branch and a reference branch, the signal branch to be modulated according to the received RF signal of interest; and a second coupler configured to recombine the modulated signal branch and the reference branch into the at least one modulated optical pulse. 7. The pADC of claim 6 , wherein: the phase drift is associated with a phase difference between the signal branch and the reference branch. 8. The pADC of claim 1 , further comprising: at least one demodulator configured to provide a digital counterpart signal corresponding to the received RF signal of interest by demodulating the at least one corrected modulated optical pulse. 9. A method for photonic phase correction in a photonic analog-digital converter (pADC), the method comprising: receiving an RF signal of interest via a passive remote sampler (PRS) of the pADC; sending a continuous-wave (CW) optical signal through the PRS in a reverse optical path; converting the CW optical signal to an electrical signal at least partially indicative of an environmental phase drift associated with the PRS; sending at least one optical pulse through the PRS in a forward optical path; modulating, via a phase modulator of the PRS, the at least one optical pulse according to the received RF signal of interest; and correcting, via a receiving side of a base unit optically coupled to the PRS, the environmental phase drift from the at least one modulated optical pulse based on the converted electrical signal. 10. The method of claim 9 , wherein the pADC includes a base unit optically coupled to the PRS, and: sending the continuous-wave (CW) optical signal through the PRS in a reverse optical path includes sending the continuous-wave (CW) optical signal through the PRS via the receiving side of the base unit; and converting the CW optical signal to the electrical signal includes converting the CW optical signal to the electrical signal via a sending side of the base unit. 11. The method of claim 9 , wherein: sending the continuous-wave (CW) optical signal through the PRS in a reverse optical path includes modulating the CW optical signal according to the received RF signal of interest; and converting the CW optical signal to the electrical signal indicative of the environmental phase drift of the PRS includes filtering a phase-error signal corresponding to the environmental phase drift from the converted electrical signal. 12. The method of claim 11 , wherein filtering the phase-error signal corresponding to the environmental phase drift from the converted electrical signal includes: filtering a phase-error signal corresponding to the environmental phase drift from the converted electrical signal based on a frequency disparity between the phase-error signal and the received RF signal of interest. 13. The method of claim 9 , wherein: sending at least one optical pulse through the PRS in a forward optical path includes splitting the at least one optical pulse into a signal branch and a reference branch; and the environmental phase drift is associated with a phase difference between the signal branch and the reference branch. 14. The method of claim 9 , wherein converting the CW optical signal to an electrical signal indicative of an environmental phase drift of the PRS includes: separating the CW optical signal from the at least one optical pulse based on a frequency disparity between the CW optical signal and the at least one optical pulse. 15. The method of claim 9 , further comprising: providing a digital counterpart signal corresponding to the received RF signal of interest by demodulating the at least one corrected modulated optical pulse.