Optical performance monitor

What is claimed is: 1. An optical performance monitor comprising: a first stage configured to receive a multiplexed optical signal, the first stage being configured to perform tunable frequency-periodic filtering on the multiplexed optical signal to produce a fine filtered optical signal; a second stage coupled to the first stage and configured to receive the fine filtered optical signal, the second stage configured to produce a pair of optical signals based on the fine filtered optical signal; and a third stage coupled to the second stage and configured to receive the pair of optical signals, the third stage configured to demultiplex the pair of optical signals to produce a plurality of demultiplexed optical signals; wherein the second stage has a second-stage transfer function, the third stage has a third-stage transfer function, and wherein, over a predetermined operating frequency range, a combination of the second-stage transfer function and the third-stage transfer function varies less than the third-stage transfer function. 2. The optical performance monitor of claim 1 , wherein the first stage is configured to pass portions of the multiplexed optical signal falling within a spaced-apart set of frequency bands, wherein center frequencies of the spaced-apart set of frequency bands are adjustable over a predetermined free spectral range by tuning of the first stage, and wherein the predetermined operating frequency range spans the free spectral range. 3. The optical performance monitor of claim 1 , wherein the second stage is configured to produce the pair of optical signals as copies of the fine filtered optical signal with specified amplitudes. 4. The optical performance monitor of claim 1 , wherein the second stage comprises a Mach-Zehnder delay interferometer configured to produce the pair of optical signals. 5. The optical performance monitor of claim 1 , wherein the second stage comprises: a switch configured to receive the fine filtered optical signal, the switch having two outputs and configured to selectably direct the fine filtered optical signal to either one of the two outputs; a first Mach-Zehnder delay interferometer (MZDI) coupled to a first output of the two outputs and configured to produce the pair of optical signals when the switch directs the fine filtered optical signal to the first output; and a second Mach-Zehnder delay interferometer (MZDI) coupled to a second output of the two outputs and configured to produce the pair of optical signals when the switch directs the fine filtered optical signal to the second output. 6. The optical performance monitor of claim 5 , wherein: the second stage has a second-stage transfer function, the third stage has a third-stage transfer function, and wherein, over a predetermined operating frequency range, a combination of the second-stage transfer function and the third-stage transfer function varies less than the third-stage transfer function; and the second stage is configured to provide the second-stage transfer function by directing the fine filtered optical signal through the first MZDI when the fine filtered optical signal falls within a first portion of the operating frequency range, and further by directing the fine filtered optical signal through the second MZDI when the fine filtered optical signal falls within a second portion of the operating frequency range. 7. The optical performance monitor of claim 1 , wherein the first stage comprises a tunable micro ring resonator. 8. The optical performance monitor of claim 1 , wherein the third stage comprises an arrayed waveguide grating (AWG). 9. The optical performance monitor of claim 8 , wherein the AWG is a multi input-multi output AWG. 10. The optical performance monitor of claim 8 , further comprising one or more calibration components operatively coupled to one or more input ports, output ports, or both, of the AWG. 11. The optical performance monitor of claim 1 , further comprising a polarization beam splitter configured to separate the multiplexed optical signal into multiple polarized components to be monitored separately. 12. The optical performance monitor of claim 1 , further comprising a controller configured to: determine a desired set of frequencies to be measured by the optical performance monitor; and control the first stage to generate plural instances of the fine filtered optical signal successively over time, said plural instances covering the desired set of frequencies. 13. The optical performance monitor of claim 1 , wherein the first stage is further controllable to adjust a bandwidth of the fine filtered optical signal, the optical performance monitor, further comprising a controller configured to adjust said bandwidth of the fine filtered optical signal based on current operating requirements. 14. The optical performance monitor of claim 1 , wherein the first stage, the second stage and the third stage collectively form a first monitoring component configured for monitoring optical signals within a first frequency band, the optical performance monitor further comprising one or more additional monitoring components each configured for monitoring optical signals within one or more additional frequency bands. 15. The optical performance monitor of claim 1 , wherein one or more of the first stage, the second stage and the third stage are fabricated in silicon photonics, silicon nitride, or another CMOS compatible technology. 16. The optical performance monitor of claim 1 , wherein at least two components of one or more of the first stage, the second stage and the third stage are fabricated using a different technology selected from: silicon photonics, silicon nitride, or another CMOS compatible technology, said at least two components being indirectly or directly optically coupled together. 17. The optical performance monitor of claim 1 , wherein the second stage comprises an optical power splitter configured to provide the pair of optical signals. 18. The optical performance monitor of claim 17 , wherein the optical power splitter comprises one or more of: a variable power splitter, a variable optical attenuator, or a directional coupler. 19. The optical performance monitor of claim 1 , further configured to receive, at the first stage along with the multiplexed optical signal, one or more optical control signals or calibration signals, and to process the one or more optical control signals or calibration signals. 20. The optical performance monitor of claim 1 , further comprising a signal processing component configured to receive output of the third stage, and to interpret said output as spectral components of the multiplexed optical signal according to operating behaviour of the optical performance monitor. 21. A controller configured to: receive an indication of a portion of a specified optical signal to monitor; cause the optical performance monitor of claim 1 to operate on the specified optical signal as the received multiplexed signal; and based on output of the optical performance monitor operating on the specified optical signal, provide one or more measurements of the optical signal. 22. The controller of claim 21 , further configured to: receive an indication of a specified frequency resolution at which to measure the specified optical signal; and cause the optical performance monitor of claim 1 to perform frequency-based measurements of the specified optical signal at the specified frequency resolution.