RF channelizer based on parametrically generated combs derived from a single master seed

We claim: 1. A radio frequency (RF) channelizer comprising: a master laser configured to generate a reference beam at a reference frequency; a splitter configured to split the reference beam into first and second beams; an RF reference oscillator; a first modulator module configured to convert the first beam into a first modulated beam comprising a multitude of frequencies spaced from the reference frequency by integer multiples of a first RF frequency that is referenced to the RF reference oscillator; a second modulator module configured to convert the second beam into a second modulated beam comprising a multitude of frequencies spaced from the reference frequency by integer multiples of a second RF frequency that is referenced to the RF reference oscillator; a first seed tone generator configured to derive a first seed tone beam from the first modulated beam; a second seed tone generator configured to derive a second seed tone beam from the second modulated beam; a first parametric mixer configured to receive and convert the first seed tone beam into a first comb; a signal modulator configured to modulate a received RF signal to be channelized onto the first comb; a second parametric mixer configured to receive and convert the second seed tone beam into a second comb; a first optical filter configured to receive and to separate the RF-signal-modulated first comb into a plurality of first filtered beams a center frequency of each first filtered beam corresponding to a frequency of an individual line of the second comb; a second optical filter configured to receive and to separate the second comb into a plurality of second filtered beams each second filtered beam corresponding to an individual line of the second comb; and a coherent detection array configured to select and down convert the received RF signal from the first and second filtered beams. 2. The RF channelizer of claim 1 , wherein the first seed tone beam comprises at least two first seed frequencies spaced by Δf P , where Δf P is a multiple of the first RF frequency, and wherein the second seed tone beam comprises at least two second seed frequencies spaced by (Δf P +δ)/n, where n is a positive integer, and the absolute value of δ is the channel spacing of the RF channelizer, and where (Δf P +δ)/n is a multiple of the second RF frequency. 3. The RF channelizer of claim 2 , wherein the first seed tone generator is configured to derive the first seed tone beam with high optical power at each first seed frequency by filtering the first modulated beam, amplifying the filtered first modulated beam, and filtering the filtered and amplified first modulated beam, and wherein the second seed tone generator is configured to derive the second seed tone beam with high optical power at each second seed frequency by filtering the second modulated beam, amplifying the filtered second modulated beam, and filtering the filtered and amplified second modulated beam. 4. The RF channelizer of claim 3 , wherein the coherent detection array is configured to select, combine, and detect corresponding pairs from the first filtered beams and the second filtered beams, and further configured to output a contiguous bank of channelized coherent I/Q down-converted intermediate frequency (IF) signals, spaced in frequency by the absolute value of δ covering the bandwidth of the received RF signal. 5. The RF channelizer of claim 4 , wherein the first and second seed tone generators each comprise; a cascade of optical filter stages configured to pass only desired seed tones; at least one optical amplifier configured to increase the power of the desired seed tones; and an optical multiplexer and narrow band filters configured to recombine the power-amplified desired seed tones into a single beam and to limit broadband noise produced by the at least one optical amplifier. 6. The RF channelizer of claim 4 , wherein the coherent detection array comprises: an array of 90 degree optical hybrids; an array of balanced photodetectors connected to the array of 90 degree optical hybrids; an array of RF filters connected to the array of balanced photodetectors; an array of linear RF amplifiers that are connected to the array of RF filters; and an array of analog-to-digital converters connected to the array of RF amplifiers. 7. The RF channelizer of claim 4 , wherein the coherent detection array comprises: an array of fiber couplers; an array of balanced photodetectors connected to the array of fiber couplers; an array of RF filters connected to the array of balanced photodetectors; an array of logarithmic RF amplifiers that are connected to the array of RF filters; and an array of analog-to-digital converters connected to the array of RF amplifiers. 8. The RF channelizer of claim 1 , wherein each of the first and second parametric mixers comprises cascaded sections of heterogeneous waveguides, wherein non-linearity and dispersion properties of each waveguide section are configured to support creation of a train of high power optical pulses before a final nonlinear section, and wherein the final nonlinear section is configured to output a spectrally broad and stable optical comb. 9. The RF channelizer of claim 8 , wherein first sections of the heterogeneous waveguides of the first and second parametric mixers are each a length of highly nonlinear fiber (HNLF) that is longitudinally strained such that the Brillouin threshold of the HNLF is beyond that of a continuous wave (CW) pump level of the first and second seed tone beams respectively, wherein the heterogeneous waveguides comprise compression sections, each being a standard single mode fiber (SMF) that matches a frequency chirp induced in a respective preceding waveguide section so as to produce a train of high power optical pulses, and wherein the final section is a dispersion-flattened HNLF. 10. The RF channelizer of claim 1 , wherein the second comb is frequency-shifted with respect the first comb to improve the spectral efficiency of the RF channelizer. 11. The RF channelizer of claim 10 , further comprising an acousto-optic modulator driven by a third RF frequency equal to δ/2, wherein the second seed tone beam comprises at least two second seed tones, spaced apart by (Δf P +2δ)/n where (Δf P +2δ)/n is a multiple of the second RF frequency, wherein an output of the second seed tone generator is connected to an input of the acousto-optic modulator, and wherein a frequency-shifted output of the acousto-optic modulator is connected to an input of the second parametric mixer, such that the second comb is shifted with respect to the first comb, such that unique RF frequencies from lower and upper side bands of a comb of signal copies which have double side bands are channelized. 12. A radio frequency (RF) channelizer comprising: a master laser configured to generate a reference beam at a reference frequency; a splitter configured to split the reference beam into first and second beams; an RF reference oscillator; a first modulator module configured to convert the first beam into a first modulated beam comprising a multitude of frequencies spaced from the reference frequency by integer multiples of a first RF frequency that is referenced to the RF reference oscillator; a second modulator module configured to convert the second beam into a second modulated beam comprising a multitude of frequencies spaced from the reference frequency by integer multiples of a second RF frequency that is referenced to the RF reference oscillator; a first seed tone generator configured to derive at least three seed beams from the first modulated beam, at least two seed beams with high optical