Variable bandwidth microring optical filter device and method with frequency tuning

The invention claimed is: 1. A device comprising: an optical interferometer configured to split an optical input into a first path defined by a first arm and a second path defined by a second arm; a first-arm microring resonator (MRR) operably coupled to the first arm for imparting a first-arm MRR frequency-dependent phase to an optical signal passing through the first arm; a second-arm MRR operably coupled to the second arm for imparting a second-arm MRR frequency-dependent phase to an optical signal passing through the second arm; a first-arm MRR tuner and a second-arm MRR tuner configured to tune the first-arm MRR frequency-dependent phase and the second-arm MRR frequency-dependent phase, respectively, such that: the first-arm MRR and second-arm MRR share a common coupling coefficient; and the first-arm MRR frequency-dependent phase is equal to the negative of the second-arm MRR frequency-dependent phase; at least one additional pair of tunable MRRs, each additional pair of tunable MRRs comprising: an additional first-arm MRR operably coupled to the first arm in series with the first-arm MRR for imparting an additional first-arm MRR frequency-dependent phase to an optical signal passing through the first arm; an additional second-arm MRR operably coupled to the second arm in series with the second-arm MRR for imparting an additional second-arm MRR frequency-dependent phase to an optical signal passing through the second arm; and an additional first-arm MRR tuner and an additional second-arm MRR tuner configured to tune the additional first-arm MRR frequency-dependent phase and the additional second-arm MRR frequency-dependent phase, respectively, independently from the first-arm MRR frequency-dependent phase and the second-arm MRR frequency-dependent phase, such that: the additional first-arm MRR and additional second-arm MRR share a common coupling coefficient different from the common coupling coefficient of the first-arm MRR and second-arm MRR; and the additional first-arm MRR frequency-dependent phase is equal to the negative of the additional second-arm MRR frequency-dependent phase; and a coupler configured to combine an optical output of the first path and an optical output of the second path to generate a filtered optical output having a filter bandwidth and filter center frequency based on: the first-arm MRR frequency-dependent phase and the second-arm MRR frequency-dependent phase; and the first-arm MRR frequency-dependent phase of each additional first-arm MRR and the second-arm MRR frequency-dependent phase of each additional second-arm MRR. 2. The device of claim 1 , wherein the optical interferometer is a Mach-Zehnder Interferometer (MZI). 3. The device of claim 2 , wherein the first-arm MRR tuner and second-arm MRR tuner each comprises a thermal tuner. 4. The device of claim 3 , wherein each thermal tuner comprises a heater operably coupled to its respective MRR. 5. The device of claim 2 , wherein each tuner comprises a thermal tuner operably coupled to its respective MRR. 6. The device of claim 2 , wherein the frequency-dependent phase of the first-arm MRR and the frequency-dependent phase of the second-arm MRR may be tuned such that: the spectral response of the filtered optical output exhibits a second-order transfer function; and the filter bandwidth may be adjusted between a minimum bandwidth and a maximum bandwidth without incurring insertion loss in the filtered optical output as a result of said bandwidth adjustment. 7. The device of claim 2 , wherein: the at least one additional pair of tunable MRRs comprises one additional pair of tunable MRRs; and the frequency-dependent phase of each of the first-arm MRR, the second-arm MRR, the additional first-arm MRR, and the additional second-arm MRR may be tuned such that: the spectral response of the filtered optical output exhibits a fourth-order transfer function; the filter bandwidth may be adjusted between a minimum bandwidth and a maximum bandwidth without incurring insertion loss in the filtered optical output as a result of said bandwidth adjustment; and the filtered optical signal has infinite attenuation at two out-of-band frequencies. 8. The device of claim 2 , wherein: the at least one additional pair of tunable MRRs comprises two additional pairs of tunable MRRs; and the frequency-dependent phase of each of the first-arm MRR, the second-arm MRR, each additional first-arm MRR, and each additional second-arm MRR may be tuned such that: the spectral response of the filtered optical output exhibits an eighth-order transfer function; the filter bandwidth may be adjusted between a minimum bandwidth and a maximum bandwidth without incurring insertion loss in the filtered optical output as a result of said bandwidth adjustment; and the filtered optical signal has infinite attenuation at six out-of-band frequencies. 9. A method comprising: using an optical interferometer to split an optical input into a first path defined by a first arm and a second path defined by a second arm; using a first-arm microring resonator (MRR) operably coupled to the first arm to apply a first frequency-dependent phase to the first path; using a second-arm MRR operably coupled to the second arm to apply a second frequency-dependent phase to the second path; using a first-arm MRR tuner and a second-arm MRR tuner to tune the first frequency-dependent phase and the second frequency-dependent phase, respectively, such that: the first-arm MRR and second-arm MRR share a common coupling coefficient; and the first frequency-dependent phase is equal to the negative of the second frequency-dependent phase; using an additional first-arm MRR operably coupled to the first arm in series with the first-arm MRR to apply a first additional frequency-dependent phase to the first path; using an additional second-arm MRR operably coupled to the second arm in series with the second-arm MRR to apply a second additional frequency-dependent phase to the second path; using an additional first-arm MRR tuner and an additional second-arm MRR tuner to tune the first additional frequency-dependent phase and the second additional frequency-dependent phase, respectively, independently from the frequency-dependent phase of the first-arm MRR and the frequency-dependent phase of the second-arm MRR, such that: the additional first-arm MRR and additional second-arm MRR share a common coupling coefficient different from the common coupling coefficient of the first-arm MRR and second-arm MRR; and the first additional frequency-dependent phase is equal to the negative of the second additional frequency-dependent phase; and using a coupler to combine an optical output of the first path and an optical output of the second path to generate a filtered optical output having a filter bandwidth and filter center frequency based on: the first frequency-dependent phase and the second frequency-dependent phase; and the first additional frequency-dependent phase and the second additional frequency-dependent phase. 10. The method of claim 9 , wherein the optical interferometer is a Mach-Zehnder Interferometer (MZI). 11. The method of claim 10 , wherein the first frequency-dependent phase and the second frequency-dependent phase may be tuned such that: the filter bandwidth may be adjusted between a minimum bandwidth and a maximum bandwidth without incurring insertion loss in the filtered optical output as a result of said bandwidth adjustment. 12. The method of claim 9 , wherein: the first frequency-dependent phase, second frequency-dependent phase, first additional frequency-dependent phase, and second additiona