Distributed traveling-wave mach-zehnder modulator driver

What is claimed is: 1. A distributed traveling wave modulator, comprising: a differential optical input for receiving an optical input carrier signal and a differential optical output for providing a modulated optical carrier signal; a plurality N of optical phase-shifters connected in series connection as N sequential modulators between said differential optical input and said differential optical output, where N is an integer equal to or greater than 2; a plurality N of driver amplifier stages, each having a respective differential driver amplifier input and a differential driver amplifier output; N−1 delay/relay stages, each having a respective differential delay/relay input and a differential delay/relay output; a first of said plurality N of driver amplifier stages having its input connected to a differential electrical data input; each of the first N−1 of said plurality N of driver amplifier stages having its output connected to a respective input of a successive one of said N−1 delay/relay stages; each of said N−1 delay/relay stages having its respective differential delay/relay output connected to the differential driver amplifier input of one of the last N−1 of said plurality N of driver amplifier stages; and each of said plurality N of driver amplifier stages having a differential signal output connected to a respective one of said N sequential modulators wherein each driver amplifier stage includes only a single type of transistor to enable high-speed operation. 2. The distributed traveling wave modulator of claim 1 , wherein N=4. 3. The distributed traveling wave modulator of claim 1 , wherein said N sequential modulators are N sequential Mach-Zehnder modulator pairs. 4. The distributed traveling wave modulator of claim 1 , wherein said distributed traveling wave modulator is an integrated structure supported on a silicon substrate. 5. The distributed traveling wave modulator of claim 1 , wherein each driver amplifier stage outputs the differential driver amplifier output with a predetermined delay from the differential driver amplifier input. 6. The distributed traveling wave modulator of claim 1 , wherein each of the plurality N of sequential optical phase shifters comprises a fixed optical length. 7. The distributed traveling wave modulator of claim 1 , further comprising a plurality of DC bias elements, each DC bias element configured to control an on state and an off state of a respective one of said plurality N of driver amplifier stages. 8. The distributed traveling wave modulator of claim 1 , each of the driver amplifier stages includes a pre-amplifier stage. 9. The distributed traveling wave modulator of claim 1 , wherein each output of each driver amplifier stage is configured to be open-collector for driving both 25Ω and 50Ω impedance modulators. 10. A method of modulating an optical signal, comprising the steps of: receiving the optical signal to be modulated at an optical input port; applying a plurality N of sequential optical phase shifts to said optical signal by operation of a plurality N of fixed-length optical phase-shifters connected in series connection as N sequential modulators, where N is greater than or equal to 2, each of said N−1 phase shifts after the first of said N phase shifts delayed by a time calculated to apply each of said N−1 phase shifts after the first of said N phase shifts at a respective time when said optical signal is passes a respective one of said N sequential modulators after the first modulator, and providing a modulated optical signal at an optical output port. 11. The method of modulating an optical signal of claim 10 , wherein N=4. 12. The method of modulating an optical signal of claim 10 , wherein said method of modulating an optical signal is performed in an integrated structure supported on a substrate. 13. The method of modulating an optical signal of claim 12 , wherein said substrate comprises a semiconductor. 14. The method of modulating an optical signal of claim 13 , wherein said semiconductor comprises silicon. 15. The method of modulating an optical signal of claim 10 , wherein said plurality N of optical phase-shifters connected in series connection as N sequential modulators are N sequential Mach-Zehnder modulator pairs. 16. The method of modulating an optical signal of claim 10 , wherein each modulator includes a driver amplifier stage, which includes only a single type of transistor to enable high-speed operation. 17. The method of modulating an optical signal of claim 16 , wherein each driver amplifier stage receives a differential input signal and outputs a differential output signal with a predetermined delay. 18. The method of modulating an optical signal of claim 16 , wherein each modulator includes a pre-amplifier stage. 19. The method of modulating an optical signal of claim 10 , wherein each output of each modulator is configured to be open-collector for driving both 25Ω and 50Ω impedance modulators.