Analog predistortion linearization for optical fiber communication links

The invention claimed is: 1. A predistorter for an electro-optical converter, comprising: a plurality of low noise RF amplifiers distributed along a transmission line that receive an RF input; second order intermodulation injection (IM2) circuitry comprising an inductively-degenerated frequency doubler to square and filter IM2 products of the RF input; a Mach-Zehnder Modulator (MZM); and feed forward circuitry for injection of IM2 to independently propagate RF intermodulation components with velocity matching to the MZM; and at least one driver to inject the RF input and RF intermodulation components into the MZM. 2. The predistorter of claim 1 , wherein the MZM is a segmented MZM (Seg-MZM), the predistorter comprising a plurality of drivers to inject the RF intermodulation components into different segments of the Seg-MZM. 3. The predistorter of claim 1 , comprising a mixer that mixes a second order distortion of the RF input with a fundamental of the RF input to generate a third order distortion (IM3) of the RF input, wherein the feed forward circuitry drives IM3 injection. 4. The predistorter of claim 3 , further comprising circuitry to square and low-pass filter the RF input to generate the second order distortion. 5. The predistorter of claim 3 , further comprising circuitry to weight the third order distortion. 6. The predistorter of claim 3 , wherein the feed forward circuitry weights IM3 according to OIP ⁢ ⁢ 3 ≅ 2 ⁢ R L ⁡ ( I EE + I BIAS )  3 ⁢ I BIAS I EE + I BIAS - 1  where I BIAS is the DC current through a circuit to generate the second order distortion, I EE is the DC current of the differential driver stage, RL is the output load resistance. 7. An electro-optical converter comprising a predistorter of claim 1 , wherein the MZM comprises a segmented MZM and the second order intermodulation injection (IM2) circuitry generates a predistorted signal that is applied to the segmented MZM. 8. The electro-optical converter of claim 7 , wherein each segment of the segmented MZM comprises differential p-i-n optical phase shifter to confine the optical field in the waveguide and linearize the MZM response through a combination of plasma dispersion and Kerr effect modulation. 9. The converter of claim 8 , wherein the MZM is implemented in a silicon and the wave guide is a p-i-n phase shifter waveguide. 10. The converter of claim 8 , wherein the driver circuit comprises an active balun. 11. The converter of claim 10 , wherein the active balun produces differential RF signals with less than 1 dB gain of mismatch over an operational range. 12. The converter of claim 1 , wherein the RF input has a broadband operational range and the second order intermodulation injection (IM2) circuitry generates predistortion to correct the RF input over more than an octave. 13. A method for linearizing an electro-optical conversion, the method comprising steps of: receiving a radio frequency (RF) signal; distributing amplification along a single-ended transmission line, wherein a delay of the transmission line is matched to group velocity of light in a Mach-Zehnder Modulator (MZM), and generating second order intermodulation injection (IM2), independently propagating RF intermodulation components with a velocity matching with the MZM and injecting the RF signal and the RF intermodulation components into the MZM. 14. The method of claim 13 , wherein receiving comprises tapping the RF signal from a travelling wave line, buffering the tapped signals; splitting the buffered signal between two paths, wherein in one path the RF signal is amplified and in an auxiliary path the RF signal is squared and low-pass filtered to generate a low-frequency IM2 component, mixing the IM2 component with the original RF signal to generate an IM3 component, and weighting the IM3 component to cancel IM3. 15. The method of claim 13 , wherein said generating generates the intermodulation components over more than an octave of the RF signal bandwidth.