Optical modulation device and method for controlling optical modulation device

The invention claimed is: 1. An optical modulation device comprising: a Mach-Zehnder (“MZ”) modulator for modulating light output continuously from a light source, based on a driving voltage and a bias voltage, to generate a light signal; a splitter for splitting the light signal; a photodiode for converting a light signal output from the splitter into an electrical signal; a log detector for detecting a difference between a local maximum value and a local minimum value of a photodiode signal output from the photodiode; a dither-signal generator for generating a dither signal during control of a driving voltage amplitude; a synchronous detector for performing synchronous detection by multiplying an output signal from the log detector by the dither signal; a bias controller for outputting a reference Direct Current (“DC”) bias voltage; a superposition circuitry for superposing the dither signal on the reference DC bias voltage and outputting a resultant voltage as the bias voltage during the control of the driving voltage amplitude and for outputting the reference DC bias voltage as the bias voltage during operations other than the control of the driving voltage amplitude; a data signal generator for generating a data signal and outputting the data signal; a check-pattern generator for outputting a check-pattern signal that is set by a user; a selector for selecting the check-pattern signal during the control of the driving voltage amplitude and for selecting the data signal during an operation; an amplifier for amplifying a signal that is selected from the check-pattern signal and the data signal and outputting the signal that is amplified by the amplifier as the driving voltage to the MZ modulator; and an amplitude setter for determining, by varying an amplitude of an output voltage from the amplifier, a plurality of amplitudes of output curves from the synchronous detector, each of which is obtained by varying the reference DC bias voltage output from the bias controller, and for setting an amplification factor of the amplifier, based on an amplitude of the output voltage from the amplifier that corresponds to an amplitude satisfying a predetermined condition, out of the plurality of the amplitudes of the output curves from the synchronous detector, during the control of the driving voltage amplitude. 2. The optical modulation device according to claim 1 , wherein the check-pattern signal is a clock signal with a frequency that is half a baud rate of the data signal. 3. The optical modulation device according to claim 1 , wherein the amplitude setter sets the amplification factor of the amplifier, based on an amplitude of the output voltage from the amplifier that corresponds to an amplitude having a maximum value, out of the plurality of the amplitudes of the output curves from the synchronous detector, when a driving voltage amplitude is a half wave voltage of the MZ modulator. 4. The optical modulation device according to claim 1 , wherein the amplitude setter sets the amplification factor of the amplifier, based on an amplitude of the output voltage from the amplifier that corresponds to an amplitude having a minimum value, out of the plurality of the amplitudes of the output curves from the synchronous detector, when a driving voltage amplitude is twice a half wave voltage of the MZ modulator. 5. The optical modulation device according to claim 1 , wherein the amplitude setter acquires the output curves from the synchronous detector, by varying the reference DC bias voltage by an amount equal to or more than a half wave voltage of the MZ modulator. 6. A method for controlling an optical modulation device, the optical modulation device including: a Mach-Zehnder (“MZ”) modulator for modulating light output continuously from a light source, based on a driving voltage and a bias voltage, to generate a light signal; a splitter for splitting the light signal; a photodiode for converting a light signal output from the splitter into an electrical signal; a log detector for detecting a difference between a local maximum value and a local minimum value of a photodiode signal output from the photodiode; a dither-signal generator for generating a dither signal during control of a driving voltage amplitude; a synchronous detector for performing synchronous detection by multiplying an output signal from the log detector by the dither signal; a bias controller for outputting a reference Direct Current (“DC”) bias voltage; a superposition circuitry for superposing the dither signal on the reference DC bias voltage and outputting a resultant voltage as the bias voltage during the control of the driving voltage amplitude and for outputting the reference DC bias voltage as the bias voltage during operations other than the control of the driving voltage amplitude; a data signal generator for generating a data signal and outputting the data signal; a check-pattern generator for outputting a check-pattern signal that is set by a user; a selector for selecting the check-pattern signal during the control of the driving voltage amplitude and for selecting the data signal during an operation; and an amplifier for amplifying a signal that is selected from the check-pattern signal and the data signal and outputting the signal that is amplified by the amplifier as the driving voltage to the MZ modulator, the method comprising the steps of: determining, by varying an amplitude of an output voltage from the amplifier, a plurality of amplitudes of output curves from the synchronous detector, each of which being obtained by varying the reference DC bias voltage output from the bias controller; and setting an amplification factor of the amplifier, based on an amplitude of the output voltage from the amplifier that corresponds to an amplitude satisfying a predetermined condition, out of the plurality of the amplitudes of the output curves from the synchronous detector.