Optical modulator module that includes a plurality of optical modulators

What is claimed is: 1. An optical modulator module comprising: a substrate in which a plurality of optical modulators are formed; a connector configured to include a plurality of terminals to which a plurality of signals for driving the plurality of optical modulators are input; and a relay board provided between the substrate and the connector, wherein each of the optical modulators includes an optical waveguide, a modulation electrode formed near the optical waveguide, and a feeder electrode electrically connected to one end of the modulation electrode, the plurality of terminals are arranged in parallel or approximately parallel to a longitudinal direction of the substrate, positions of respective ends of the modulation electrodes at which the respective feeder electrodes of respective optical modulators are electrically connected are substantially the same as positions at which the respective terminals are provided in the longitudinal direction of the substrate, a plurality of wiring patterns are formed on the relay board so as to electrically connect the plurality of terminals to the respective feeder electrodes of the optical modulators, and the plurality of optical modulators are arranged in parallel or approximately parallel to the longitudinal direction of the substrate and are arranged at positions that are shifted in sequence in accordance with spacing between the terminals of the connector in the longitudinal direction. 2. The optical modulator module according to claim 1 , wherein the plurality of wiring patterns are formed to be parallel or approximately parallel to each other on the relay board. 3. An optical modulator module comprising: a substrate in which a plurality of optical modulators are formed; a connector configured to include a plurality of terminals to which a plurality of signals for driving the plurality of optical modulators are input; and a relay board provided between the substrate and the connector, wherein each of the optical modulators includes an optical waveguide, a modulation electrode formed near the optical waveguide, and a feeder electrode electrically connected to one end of the modulation electrode, the plurality of terminals are arranged in parallel or approximately parallel to a longitudinal direction of the substrate, positions of respective ends of the modulation electrodes at which the respective feeder electrodes of respective optical modulators are electrically connected are substantially the same as positions at which the respective terminals are provided in the longitudinal direction of the substrate, a plurality of wiring patterns are formed on the relay board so as to electrically connect the plurality of terminals to the respective feeder electrodes of the optical modulators, a first optical modulator, a second optical modulator, a third optical modulator and a fourth optical modulator are formed in the substrate, the connector includes a first terminal, a second terminal, a third terminal and a fourth terminal corresponding to the first optical modulator, the second optical modulator, the third optical modulator and the fourth optical modulator, the first optical modulator, the second optical modulator, the third optical modulator and the fourth optical modulator are arranged in sequence along the longitudinal direction of the substrate, and a positional shifting amount of the second optical modulator with respect to the first optical modulator in the longitudinal direction of the substrate is equal or approximately equal to spacing between the first terminal and the second terminal, a positional shifting amount of the third optical modulator with respect to the second optical modulator in the longitudinal direction of the substrate is equal or approximately equal to spacing between the second terminal and the third terminal, and a positional shifting amount of the fourth optical modulator with respect to the third optical modulator in the longitudinal direction of the substrate is equal or approximately equal to spacing between the third terminal and the fourth terminal. 4. The optical modulator module according to claim 1 , wherein a stepwise polarization inversion area is formed on the substrate so that the polarization inversion area is disposed approximately in middle portions of the respective optical modulators. 5. The optical modulator module according to claim 1 , wherein a parallelogrammic polarization inversion area is formed on the substrate so that the polarization inversion area is disposed approximately in middle portions of the respective optical modulators. 6. An optical transmitter including a signal generation circuit configured to generate a plurality of drive signals and an optical modulator module configured to be driven in accordance with the plurality of drive signals, wherein the optical modulator module includes: a substrate in which a plurality of optical modulators driven in accordance with the plurality of drive signals are formed; a connector configured to include a plurality of terminals to which the plurality of drive signals are input; and a relay board provided between the substrate and the connector, wherein each of the optical modulators includes an optical waveguide, a modulation electrode formed near the optical waveguide, and a feeder electrode electrically connected to one end of the modulation electrode, the plurality of terminals are arranged in parallel or approximately parallel to a longitudinal direction of the substrate, positions of respective ends of the modulation electrodes at which the respective feeder electrodes of respective optical modulators are electrically connected are substantially the same as positions at which the respective terminals are provided in the longitudinal direction of the substrate, a plurality of wiring patterns are formed on the relay board so as to electrically connect the plurality of terminals to the respective feeder electrodes of the optical modulators, and the signal generation circuit adjusts phases or timings of the plurality of drive signals so that differences of lengths of transmission routes of the plurality of drive signals between the connector and the plurality of optical modulators are compensated for.