Driving device and driving method for phase controller, and optical switch

The invention claimed is: 1. An optical device comprising: two input ports; two output ports; first and second optical couplers arranged in series between the input ports and the output ports; first and second optical waveguides extending in parallel while connecting the first and second optical couplers to each other; a first phase controller provided on the first optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the first optical waveguide using a first heater to control a phase of light propagating therethrough; a second phase controller provided on the second optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the second optical waveguide using a second heater to control a phase of light propagating therethrough; and a pulse generation circuit for applying pulse-width modulated voltage pulses with predefined average power to the first and second heaters to control a phase difference between the first and second waveguides, wherein, when switching from a cross state to a bar state or from the bar state to the cross state by raising the temperature of the second heater, the pulse generation circuit is configured to: apply a voltage pulse being on constantly for a certain period of time to the first heater, and thereafter, apply a plurality of consecutive voltage pulses having a first pulse-width to the first heater and a plurality of consecutive voltage pulses having a third pulse-width to the second heater instead of a plurality of consecutive voltage pulses having a second pulse-width, and gradually shorten the first pulse width and the third pulse width. 2. An optical device comprising: two input ports; two output ports; first and second optical couplers arranged in series between the input ports and the output ports; first and second optical waveguides extending in parallel while connecting the first and second optical couplers to each other; a first phase controller provided on the first optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the first optical waveguide using a first heater to control a phase of light propagating therethrough; a second phase controller provided on the second optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the second optical waveguide using a second heater to control a phase of light propagating therethrough; and a pulse generation circuit for applying pulse-width modulated voltage pulses with predefined average power to the first and second heaters to control a phase difference between the first and second waveguides, wherein, when switching from a cross state to a bar state or from the bar state to the cross state by raising the temperature of the second heater, the pulse generation circuit is configured to: apply a voltage pulse being on constantly for a certain period of time to the first heater, and thereafter, apply a plurality of consecutive voltage pulses having a first pulse-width to the first heater and a zero-pulse state to the second heater instead of a plurality of consecutive voltage pulses having a second pulse-width. 3. An optical device comprising: two input ports; two output ports; first and second optical couplers arranged in series between the input ports and the output ports; first and second optical waveguides extending in parallel while connecting the first and second optical couplers to each other; a first phase controller provided on the first optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the first optical waveguide using a first heater to control a phase of light propagating therethrough; a second phase controller provided on the second optical waveguide between the first optical coupler and the second optical coupler and for controlling a temperature of the second optical waveguide using a second heater to control a phase of light propagating therethrough; and a pulse generation circuit for applying pulse-width modulated voltage pulses with predefined average power to the first and second heaters to control a phase difference between the first and second waveguides, wherein, when switching from a cross state to a bar state or from the bar state to the cross state by raising the temperature of the second heater, the pulse generation circuit is configured to: apply a voltage pulse being on constantly for a certain period of time to the first heater and a zero-pulse state to the second heater instead of a plurality of consecutive voltage pulses having a second pulse-width, and thereafter, apply a plurality of consecutive voltage pulses having a first pulse-width to the first heater.