Optical modulation apparatus, optical transmitter and controlling method for optical modulator

What is claimed is: 1. An optical transmitter, comprising: a light source that outputs light having one wavelength; an optical modulation unit that is coupled to the light source and includes a plurality of ring optical modulators individually including a first optical waveguide, a second optical waveguide, a ring optical waveguide optically coupled between the first optical waveguide and the second optical waveguide, a modulation electrode that is provided on the ring optical waveguide and to which a modulation electric signal is supplied, and a resonance wavelength adjustment electrode provided on the ring optical waveguide for adjusting a resonance wavelength, the plurality of ring optical modulators being coupled in cascade to each other, the ring optical waveguides of the plurality of ring optical modulators having round-trip lengths different from each other; and a controller that performs, for at least one of the plurality of ring optical modulators, first resonance wavelength adjustment control to adjust the resonance wavelength of the ring optical modulator to the one input light wavelength inputted from the light source, performs second resonance wavelength adjustment control to specify the ring optical modulator that exhibits a minimum current amount required for the adjustment of the resonance wavelength of the ring optical waveguide to the one input light wavelength from among the plurality of ring optical modulators, to supply current to the resonance wavelength adjustment electrode of the specified ring optical modulator, thereby to adjust the resonance wavelength of the specified ring optical modulator to the one input light wavelength, and performs modulation driving control by supplying a modulation electric signal to the modulation electrode of the specified ring optical modulator. 2. An optical transmitter, comprising: a plurality of light sources that output light having wavelengths different from each other; a plurality of optical modulation units that are coupled one by one to the plurality of light sources and individually include a plurality of ring optical modulators individually including a first optical waveguide, a second optical waveguide, a ring optical waveguide optically coupled between the first optical waveguide and the second optical waveguide, a modulation electrode that is provided on the ring optical waveguide and to which a modulation electric signal is supplied, and a resonance wavelength adjustment electrode provided on the ring optical waveguide for adjusting a resonance wavelength, the plurality of ring optical modulators being coupled in cascade to each other, the ring optical waveguides of the plurality of ring optical modulators having round-trip lengths different from each other; an optical multiplexer coupled to the plurality of optical modulation units; and a controller that performs, for at least one of the plurality of ring optical modulators of each of the plurality of optical modulation units, first resonance wavelength adjustment control to adjust the resonance wavelength of the ring optical modulator to one input light wavelength inputted from one of the light sources, performs second resonance wavelength adjustment control to specify the ring optical modulator that exhibits a minimum current amount required for the adjustment of the resonance wavelength of the ring optical waveguide to the one input light wavelength from among the plurality of ring optical modulators, to supply current to the resonance wavelength adjustment electrode of the specified ring optical modulator, thereby to adjust the resonance wavelength of the specified ring optical modulator to the one input light wavelength, and performs modulation driving control by supplying a modulation electric signal to the modulation electrode of the specified ring optical modulator. 3. The optical transmitter according to claim 2 , wherein the resonance wavelength adjustment electrode is a heater electrode to which current is supplied in order to adjust the resonance wavelength of the ring optical modulator to heat the ring optical waveguide. 4. The optical transmitter according to claim 2 , wherein the resonance wavelength adjustment electrode is a carrier injection electrode to which current is supplied in order to adjust the resonance wavelength of the ring optical modulator to inject carriers into the ring optical waveguide. 5. The optical transmitter according to claim 2 , wherein, in a state in which the modulation electric signal is not supplied to the modulation electrode and current is not supplied to the resonance wavelength adjustment electrode, mutual intervals between the resonance wavelengths of the plurality of ring optical modulators are substantially equal to each other. 6. The optical transmitter according to claim 2 , further comprising: first switches connected one by one to the resonance wavelength adjustment electrodes of the plurality of ring optical modulators; and second switches connected one by one to the modulation electrodes of the plurality of ring optical modulators; wherein the controller performs control for changing over the first switches in order to select the ring optical modulator for which the first and second resonance wavelength adjustment controls are to be performed and performs control for changing over the second switches in order to select the ring optical modulator for which the modulation driving control is to be performed. 7. The optical transmitter according to claim 2 , further comprising a photodetector coupled to the first optical waveguide or the second optical waveguide; wherein the controller performs the first resonance wavelength adjustment control based on information detected by the photodetector.