Self-tuned silicon-photonic WDM transmitter

What is claimed is: 1. An optical transmitter, comprising: a set of reflective silicon optical amplifiers (RSOAs), which includes two or more RSOAs; a set of ring modulators, which modulate optical signals based on electrical input signals; a shared broadband reflector; a set of intermediate waveguides, wherein each intermediate waveguide in the set is coupled to an RSOA in the set of RSOAs, and channels light from the RSOA in proximity to an associated ring modulator in the set of ring modulators to cause optically coupled light to circulate in the associated ring modulator; and a shared waveguide with a first and a second end, wherein the first end is coupled to the shared broadband reflector, and wherein the shared waveguide passes in proximity to the set of ring modulators, so that light circulating in each ring modulator in the set causes optically coupled light to flow in the shared optical waveguide; and wherein each RSOA in the set of RSOAs forms a lasing cavity, which includes an associated intermediate waveguide in the set of intermediate waveguides, an associated ring modulator in the set of ring modulators, the shared waveguide and the shared broadband reflector; wherein each lasing cavity has a different wavelength, which is determined by a resonance of the associated ring modulator; and wherein the different wavelengths in each of the lasing cavities are combined in the shared waveguide to produce a combined output that emanates from the second end of the shared waveguide. 2. The optical transmitter of claim 1 , wherein each ring modulator in the set of ring modulators simultaneously performs three operations, including: wavelength discrimination; high-speed modulation; and wavelength multiplexing onto the shared waveguide. 3. The optical transmitter of claim 1 , wherein each lasing cavity includes a thermo-optic coefficient (TOC) compensator comprising a section of compensation material; wherein the lasing cavity includes a length l Si through silicon, a length l C through the compensation material, and a length l OGM through the optical gain material; wherein the effective refractive index of silicon is n Si , the effective refractive index of the compensation material is n C , and the effective refractive index of the optical gain material is n OGM ; wherein the effective TOC of silicon is dn Si /dT, the effective TOC of the compensation material is dn C /dT, and the effective TOC of the optical gain material is dn OGM /dT; and wherein lc≈l OGM *(dn OGM /dT−dn Si /dT)/(dn Si /dT−dn C /dT), whereby the effective TOC of a portion of the lasing cavity that passes through the optical gain material and the compensation material is substantially the same as the TOC of silicon. 4. The optical transmitter of claim 1 , wherein the set of RSOAs are located on one or more gain chips, which are separate from a semiconductor chip that includes the set of intermediate waveguides, the set of ring modulators, the shared waveguide, and the shared broadband reflector. 5. The optical transmitter of claim 1 , wherein each ring modulator in the set of ring modulators includes a thermal-tuning mechanism. 6. The optical transmitter of claim 1 , wherein each ring modulator in the set of ring modulators comprises a coupled dual-ring modulator. 7. The optical transmitter of claim 6 , wherein each coupled dual-ring modulator includes two rings, which have aligned resonances that are tuned to be offset from each other, so that the coupled dual-ring modulator functions as a filter with a flat-top response, which is aligned with an associated lasing cavity mode. 8. The optical transmitter of claim 6 , wherein each coupled dual-ring modulator includes two rings having different radii, which causes a Vernier effect that provides a combined tuning range that is larger than the gain bandwidth of an associated RSOA. 9. The optical transmitter of claim 1 , wherein the shared broadband reflector comprises one of the following: a loop mirror with a 50/50 directional coupler; a loop mirror with a Y-junction; and a waveguide distributed Bragg reflector (DBR). 10. A system, comprising: at least one processor; at least one memory coupled to the at least one processor; and an optical transmitter for communicating optical signals generated by the system, wherein the optical transmitter includes: a set of reflective silicon optical amplifiers (RSOAs), which includes two or more RSOAs; a set of ring modulators, which modulate optical signals based on electrical input signals; a shared broadband reflector; a set of intermediate waveguides, wherein each intermediate waveguide in the set is coupled to an RSOA in the set of RSOAs, and channels light from the RSOA in proximity to an associated ring modulator in the set of ring modulators to cause optically coupled light to circulate in the associated ring modulator; and a shared waveguide with a first and a second end, wherein the first end is coupled to the shared broadband reflector, and wherein the shared waveguide passes in proximity to the set of ring modulators, so that light circulating in each ring modulator in the set causes optically coupled light to flow in the shared optical waveguide; wherein each RSOA in the set of RSOAs forms a lasing cavity, which includes an associated intermediate waveguide in the set of intermediate waveguides, an associated ring modulator in the set of ring modulators, the shared waveguide and the shared broadband reflector; wherein each lasing cavity has a different wavelength, which is determined by a resonance of the associated ring modulator; and wherein the different wavelengths in each of the lasing cavities are combined in the shared waveguide to produce a combined output that emanates from the second end of the shared waveguide. 11. The system of claim 10 , wherein each ring modulator in the set of ring modulators simultaneously performs three operations, including: wavelength discrimination; high-speed modulation; and wavelength multiplexing onto the shared waveguide. 12. The system of claim 10 , wherein each lasing cavity includes a thermo-optic coefficient (TOC) compensator comprising a section of compensation material; wherein the lasing cavity includes a length l Si through silicon, a length l C through the compensation material, and a length l OGM through the optical gain material; wherein the effective refractive index of silicon is n Si , the effective refractive index of the compensation material is n C , and the effective refractive index of the optical gain material is n OGM ; wherein the effective TOC of silicon is dn Si /dT, the effective TOC of the compensation material is dn C /dT, and the effective TOC of the optical gain material is dn OGM /dT; and wherein lc≈l OGM *(dn OGM /dT−dn Si /dT)/(dn Si /dT−dn C /dT), whereby the effective TOC of a portion of the lasing cavity that passes through the optical gain material and the compensation material is substantially the same as the TOC of silicon. 13. The system of claim 10 , wherein the set of RSOAs are located on one or more gain chips, which are separate from a semiconductor chip that includes the set of intermediate waveguides, the set of ring modulators, the shared waveguide, and the shared broadband reflector. 14. The system of claim 10 , wherein each ring modulator in the set of ring modulators includes a thermal-tuning mechanism. 15. The system of claim 10 , wherein each ring modulator in the set of ring modulators comprises a coupled dual-ring modulator. 16. The system of claim 15 , wherein each coupled dual