Variable gain optical modulator with open collector driver amplifier and method of operation

What is claimed is: 1 . A distributed amplifier for an optic signal generator comprising: two or more amplifier cells, each cell having: one or more emitter follower circuits having an emitter follower input and an emitter follower output configured to perform frequency specific gain adjustment; two or more amplifiers comprising in a cascode connected transistors configurated to amplify the received signal to create an amplified signal; an amplifier cell output configured to carry the amplified signal; an input path configured to receive the input signal and distribute the input signal to the two or more amplifier cells, the input path including one or more inductors that cancel parasitic capacitance from the two or more amplifier cells; and an output path connected to the amplifier cell output of the two or more amplifier cells to receive the amplified signal, the output path including one or more inductors that cancel parasitic capacitance from the two or more amplifier cells. 2 . The distributed driver of claim 1 wherein an inductor from the input path and an inductor from the output path is associated with each amplifier cell. 3 . The distributed driver of claim 1 wherein the combination of the amplifier parasitic capacitance and the inductors in the input path and the output path form a transmission line that tunes out the parasitic capacitance from the two or more amplifier cells. 4 . The distributed driver of claim 1 wherein the two or more amplifier cells are configured in an open collector configuration. 5 . The distributed driver of claim 1 wherein the emitter follower circuit further comprises a variable current source configured to control the frequency specific gain adjustment. 6 . The distributed driver of claim 1 further comprising a termination network and gain shaping network, connected to or part of the input path, configured to perform gain shaping. 7 . The distributed driver of claim 1 wherein the amplifier cell input comprises a first input and a second input, the first and second inputs are configured to accept a differential signal, and the first input connects to a first emitter follower circuit and the second input connects to a second emitter follower circuit. 8 . A method for amplifying, with a distributed amplifier, an input signal for use in an optic signal communication system, the method comprising: receiving the input signal, the input signal to be transmitted on an optic fiber as an optic signal; distributing the input signal to two or more emitter follower circuits over an input path having an inductance, the input path having an inductance that cancels a parasitic capacitance of the two or more amplifier cells; introducing frequency specific adjustment to the input signal for gain peaking, gain shaping, or both, with two or more emitter follower circuits; amplifying the input signal after frequency specific adjustment with two or more amplifier cells to generate amplified output signals; combining the amplified output signals from the two or more amplifier cells on an output path as a combined output signal, the output path having an inductance that cancels a parasitic capacitance of the two or more amplifier cells; and presenting the combined output signal on an output from the distributed amplifier, the output connected to the output path. 9 . The method of claim 8 wherein an inductor from the input path and an inductor from the output path is associated with each amplifier cell, and the inductors are realized as integrated transmission line elements. 10 . The method of claim 8 wherein the combination of the amplifier parasitic capacitance and the inductors in the input path and the output path form a transmission line that tunes out the parasitic capacitance from the two or more amplifier cells. 11 . The method of claim 8 wherein the two or more amplifier cells are configured in an open collector configuration. 12 . The method of claim 8 wherein the emitter follower circuit includes a variable current source configured to control the frequency specific gain control. 13 . The distributed driver of claim 8 further comprising providing a control signal to a variable current source that is part of the emitter follower circuit, such that the control signal determines the amount of frequency specific gain adjustment. 14 . The method of claim 8 wherein the two or more amplifier cells further comprise a first input and a second input, the first and second inputs are configured to accept a differential signal, and the first input connects to a first emitter follower circuit and the second input connect to a second emitter follower circuit. 15 . A distributed driver for an optic signal generator comprising: a driver input configured to receive an input signal; an output configured to provide an output signal to the optic signal generator or modulator; a first amplifier cell comprising a first amplifier cell input, one or more emitter follower circuits, one or more amplifiers, and a first amplifier cell output, the first amplifier cell configured to receive and amplify the input signal to create a first amplified signal on the first amplifier cell output; a second amplifier cell comprising a second amplifier cell input, one or more emitter follower circuits, one or more amplifiers, and a second amplifier cell output, the second amplifier cell configured to receive and amplify the input signal to create a second amplified signal on the second amplifier cell output; a first conductive path connecting the driver input to the first amplifier cell input and the second amplifier cell input, the first conductive path carrying the input signal to the first amplifier cell and the second amplifier cell such that an inductance of the first conductive path counteracts a capacitance associated with the first amplifier cell and the second amplifier cell; and a second conductive path connecting the driver output to the first amplifier cell output and the second amplifier cell output, the second conductive path carrying the first amplified signal and the second amplifier signal to the driver output, such that an inductance of the second conductive path counteracts the capacitance associated with the first amplifier cell and the second amplifier cell. 16 . The distributed driver of claim 15 wherein the one or more amplifiers are configured as a cascode connected differential pair. 17 . The distributed driver of claim 15 further comprising additional amplifiers cells having a configuration that is the same as the first amplifier cell and the second amplifier cell. 18 . The distributed driver of claim 15 wherein first amplifier cell and the second amplifier cell have an open collector configuration. 19 . The distributed driver of claim 15 wherein the one or more emitter follower circuits further comprise a variable current source configured to control a frequency specific gain adjustment. 20 . The distributed driver of claim 15 further comprising a termination network and gain shaping network, connected to or part of the first conductive path, configured to perform frequency specific gain shaping.