Microwave photonic notch filter

The invention claimed is: 1. A filter for generating a copy of an electrical signal with suppressed frequency components within a selected frequency band, the filter comprising: a modulator to generate a modulated optical signal that is modulated with the electrical signal and has a first sideband and a second sideband; a configurable optical processor configured to modify the modulated optical signal to generate a modified optical signal by adjusting the power of the first sideband or the power of the second sideband or both to produce a difference between the power of the first sideband and the power of the second sideband and by producing an antiphase relationship between light within the first side band corresponding to the selected frequency band and light within the second side band corresponding to the selected frequency band; an optical resonant filter to adjust the power of the first side band of the modified optical signal corresponding to the selected frequency band by a resonance power adjustment to generate a resonance output signal; an optical-to-electrical converter to combine the resonance output signal with the second side band of the modulated signal to generate a copy of the electrical signal with suppressed frequency components within the selected frequency band; and a control unit to re-configure the configurable optical processor to adjust the difference between the power of the first sideband and the power of the second sideband towards the resonance power adjustment. 2. The filter of claim 1 , wherein the modulator comprises a light source that is controlled by the electrical signal to generate the modulated optical signal. 3. The filter of claim 1 , wherein the modulator is configured to modulate an input optical wave with the electrical signal. 4. The filter of claim 3 , wherein the modulator is a phase modulator. 5. The filter of claim 1 , wherein the first side band of the modulated optical signal generated by the modulator has equal power to the second side band of the modulated optical signal generated by the modulator. 6. The filter of claim 1 , wherein the configurable optical processor comprises a waveshaper. 7. The filter of claim 1 , wherein the configurable optical processor comprises a Fourier domain optical processor. 8. The filter of claim 1 , wherein the optical processor comprises: a first optical path; a second optical path; a wavelength selective splitter to guide the first sideband onto the first optical path and the second sideband onto the second optical path; a configurable power adjustor in one or both of the first optical path and the second optical path to adjust the power of one or both of the first optical path and the second optical path. 9. The filter of claim 8 , wherein the power adjustor comprises a configurable attenuator. 10. The filter of claim 8 , wherein one or both of the first optical path and the second optical path comprise a configurable phase shifter to produce the antiphase relationship between light within the first side band corresponding to the selected frequency band and light within the second side band corresponding to the selected frequency band. 11. The filter of claim 1 , wherein the filter is integrated into a photonic chip. 12. The filter claim 1 , wherein the optical resonant filter comprises stimulated Brillouin scattering. 13. The filter of claim 1 , wherein the optical resonant filter comprises a resonance ring. 14. A method for generating a copy of an electrical signal with suppressed frequency components within a selected frequency band, the method comprising: generating a modulated optical signal that is modulated with the electrical signal and has a first sideband and a second sideband; using a configurable optical processor to modify the modulated optical signal to generate a modified optical signal by adjusting the power of the first sideband or the power of the second sideband or both to produce a difference between the power of the first sideband and the power of the second sideband and by producing an antiphase relationship between light within the first side band corresponding to the selected frequency band and light within the second side band corresponding to the selected frequency band; coupling the modified optical signal into an optical resonant filter to adjust the power of the first side band of the modulated optical signal corresponding to the selected frequency band by a resonance power adjustment to generate a resonance output signal; combining the resonance output signal with the second side band of the modulated signal to generate a copy of the electrical signal with suppressed frequency components within the selected frequency band; and re-configuring the configurable optical processor to adjust the difference between the power of the first sideband and the power of the second sideband towards the resonance power adjustment.