Electro-optical modulator interface

That which is claimed is: 1. An integrated electro-optical modulator interface comprising: a two-branch output stage comprising a plurality of thin oxide CMOS transistors configured to generate rail-to-rail output swings larger than twice a nominal limit of a supply voltage of said plurality of thin oxide CMOS transistors, each branch of said two-branch output stage comprising two stacked CMOS inverter pairs from among said plurality of thin oxide CMOS transistors; said two stacked CMOS inverter pairs of a given branch being configured to drive a respective load capacitance, in phase opposition to the other branch; and a pre-driver circuit configured to receive a differential modulating signal and output, to respective inputs of said two stacked CMOS inverters, two synchronous differential voltage drive signals having a swing of half the supply voltage and being DC-shifted by half of the supply voltage with respect to each other. 2. The integrated electro-optical modulator interface of claim 1 , further comprising circuitry tying middle nodes of each branch of said two-branch output stage to one of respective supply voltage rails and an additional half supply voltage rail. 3. The integrated electro-optical modulator interface of claim 1 , further comprising one of a lumped bypass capacitance and a distributed R-L-C structure including a plurality of lumped capacitances coupled in a low impedance signal path at a high frequency between respective supply voltage rails. 4. The integrated electro-optical modulator interface of claim 1 , wherein said pre-driver circuit comprises an input impedance matching stage, a DC shifting stage coupled to said input impedance matching stage, and a signal amplification core stage coupled to said input impedance matching stage. 5. The integrated electro-optical modulator interface of claim 4 , wherein said DC shifting stage comprises a plurality of capacitances configured to be pre-charged to half the supply voltage. 6. The integrated electro-optical modulator interface of claim 5 , wherein said DC shifting stage further comprises a plurality of back-to-back inverter latches configured to maintain a charge of said plurality of capacitances and maintain the two synchronous differential voltage drive signals in phase opposition. 7. An electro-optical modulator interface comprising: a two-branch output stage, each branch comprising a plurality of stacked CMOS inverter pairs; said plurality of stacked CMOS inverter pairs of a given branch being configured to drive a respective load capacitance in phase opposition to the other branch; and a pre-driver circuit coupled to said plurality of stacked CMOS inverter pairs and configured to generate two synchronous differential voltage drive signals having a swing of half a supply voltage and being DC-shifted by half of the supply voltage with respect to each other. 8. The electro-optical modulator interface of claim 7 , further comprising circuitry coupling middle nodes of each branch of said two-branch output stage to one of respective supply voltage rails and an additional half supply voltage rail. 9. The electro-optical modulator interface of claim 7 , further comprising one of a lumped bypass capacitance and a distributed R-L-C structure comprising a plurality of lumped capacitances coupled between respective supply voltage rails. 10. The electro-optical modulator interface of claim 7 , wherein said pre-driver circuit comprises an input impedance matching stage, a DC shifting stage coupled to said input impedance matching stage, and a signal amplification core stage coupled to said input impedance matching stage. 11. The electro-optical modulator interface of claim 10 , wherein said DC shifting stage comprises a plurality of capacitances configured to be pre-charged to half the supply voltage. 12. The electro-optical modulator interface of claim 11 , wherein said DC shifting stage further comprises back-to-back inverter latches configured to maintain a charge of said plurality of capacitances and maintain the two synchronous differential voltage drive signals in phase opposition. 13. A method of electro-optical interfacing using an electro-optical modulator interface comprising a two-branch output stage, each branch comprising a plurality of stacked CMOS inverter pairs, the method comprising: driving, using the plurality of stacked CMOS inverter pairs of a given branch, a respective load capacitance coupled between an output of each of the plurality of stacked CMOS inverter pairs in phase opposition to the other branch; and generating, using a pre-driver circuit coupled to the plurality of stacked CMOS inverter pairs, two synchronous differential voltage drive signals having a swing of half a supply voltage and being DC-shifted by half of the supply voltage with respect to each other. 14. The method of claim 13 wherein the pre-driver circuit comprises an input impedance matching stage, a DC shifting stage coupled to said input impedance matching stage, and a signal amplification core stage coupled to said input impedance matching stage. 15. The method of claim 14 , further comprising pre-charging a plurality of capacitances of the DC shifting stage to half the supply voltage. 16. The method of claim 15 , further comprising maintaining, using back-to-back inverter latches of the DC shifting stage, a charge of the plurality of capacitances and maintaining the two synchronous differential voltage drive signals in phase opposition.