Single source full-duplex fiber optic telemetry

What is claimed is: 1. A full-duplex borehole communication system comprising: a light source to generate a light signal; a downlink modulator coupled to the light source to modulate the light signal, in response to downlink data, using a first protocol to generate a first modulated light signal; an uplink modulator coupled to the downhole modulator to modulate the first modulated light signal, in response to uplink data, using a second protocol to generate a second modulated light signal; a downlink receiver coupled to the downlink modulator to demodulate the first modulated signal to recover the downlink data; and an uplink receiver coupled to the uplink modulator and configured to demodulate the second modulated light signal to recover the downlink data and the uplink data, wherein the first protocol is asymmetric with respect to the second protocol. 2. The system of claim 1 , wherein the light source is located at one of either a downlink location or a formation surface location. 3. The system of claim 1 , further comprising: a circulator coupled to the downlink modulator and the uplink receiver; and a coupler coupled between the circulator and the downlink receiver and between the circulator and the uplink modulator; wherein, the circulator is configured to couple the first modulated light signal to the coupler and the second modulated signal to the uplink receiver. 4. The system of claim 1 , wherein the uplink receiver comprises: a filter to separate the first modulated light signal from the second modulated light signal; and a plurality of demodulators to recover the downlink data and the uplink data from the first modulated light signal and the second modulator light signal, respectively. 5. The system of claim 1 , wherein the first and second protocols modulate an optical amplitude of the light signal. 6. The system of claim 1 , wherein the first and second protocols modulate an optical phase of the light signal. 7. The system of claim 1 , wherein the first protocol is mutually orthogonal with the second protocol. 8. The system of claim 1 , wherein the first protocol generates a subcarrier signal that alternates in frequency with a subcarrier signal generated by the second protocol. 9. The system of claim 1 , wherein the first and second protocols perform orthogonal frequency division multiplexing using an orthogonal basis set of subcarriers. 10. A method comprising: modulating a light signal at a downlink modulator to generate a first modulated light signal, in response to downlink data, using a first protocol; modulating the first modulated light signal at an uplink modulator, in response to uplink data, using a second protocol to generate a second modulated light signal; and demodulating the second modulated light signal at an uplink receiver to recover the downlink data and the uplink data; wherein the first and second protocols are asymmetric with respect to each other. 11. The method of claim 10 , further comprising demodulating the first modulated light signal at a downlink receiver to recover the downlink data. 12. The method of claim 10 , wherein the first and second protocols comprise orthogonal frequency division multiplexing modulation schemes. 13. The method of claim 12 , wherein a first modulation spectra of the first modulated light signal overlaps with a second modulation spectra of the second modulated light signal wherein the first modulation spectra is orthogonal to the second modulation spectra. 14. The method of claim 10 , further comprising the first protocol encoding the downlink data in alternating subcarriers with the second protocol encoding the uplink data. 15. A system comprising: a light source to generate a light signal; a surface portion coupled to the light source, the surface portion comprising: a downlink modulator coupled to the light source and configured to modulate the light signal to generate, over a fiber optic channel, a first modulated light signal in response to downlink data and a first protocol; and an uplink receiver coupled to the fiber optic channel and configured to recover the downlink data and uplink data from a second modulated light signal; and a downhole portion coupled to the surface portion over the fiber optic channel, the downhole portion comprising: an uplink modulator configured to generate the second modulated light signal in response to the uplink data and a second protocol; and a downlink receiver, coupled to the fiber optic channel and configured to recover the downlink data, wherein the first protocol is asymmetric with respect to the second protocol. 16. The system of claim 15 , further comprising a second fiber optic channel that couples the light source to the uplink modulator and a downlink mixer, wherein the light signal is a reference signal to the downlink mixer. 17. The system of claim 16 , wherein the surface control circuitry further comprises: a first coupler that couples the light source to the downlink modulator and the second fiber optic channel, wherein the coupler provides a second light signal from the light source; a polarization controller coupled to the coupler to provide a polarized light signal; a circulator that couples the first modulated light signal to the downhole control circuitry, the circulator further couples the second modulated light signal to an uplink mixer; and the uplink mixer that couples the polarization controller and the circulator to the uplink receiver, wherein the uplink mixer is configured to generate an uplink mixed light signal in response to the polarized light signal and the second modulated light signal; and the downhole control circuitry further comprises: a downlink mixer coupled to the downlink receiver; a second coupler that couples the light signal to the downlink mixer and the uplink modulator such that the downlink mixer is configured to generate a downlink mixed signal in response to the reference signal and the first modulated light signal; and a third coupler that couples the first modulated light signal to the downlink mixer and the second modulated light signal to the fiber optic channel. 18. The system of claim 17 , further comprising a frequency filter in the uplink receiver. 19. The system of claim 15 , further comprising a second fiber optic channel that couples the first modulated light signal to the uplink modulator and a downlink mixer, wherein the light signal is a reference signal to the downlink mixer. 20. The system of claim 19 , wherein the surface control circuitry further comprises: a first coupler that couples the light source to the downlink modulator and a polarization controller, the polarization controller configured to provide a polarized light signal; a second coupler that couples the first modulated light signal to the downhole control circuitry and a circulator; the circulator that couples the first modulated light signal to the downhole control circuitry, the circulator further couples the second modulated light signal to an uplink mixer; and the uplink mixer that couples the polarization controller and the circulator to the uplink receiver, wherein the uplink mixer is configured to generate an uplink mixed light signal in response to the polarized light signal and the second modulated light signal; and the downhole control circuitry further comprises: a downlink mixer coupled to the downlink receiver; a third coupler that couples the light signal to the downlink mixer and the uplink modulator such that