Optical node device, optical transport network system, optical path trace method and program

The invention claimed is: 1. An optical node device comprising: a transmission transponder for transmitting an optical signal via an optical path extended over an optical fiber; a wavelength selective switch (WSS) for multiplexing, on the transmitted optical signal, a monitoring control signal for performing optical path tracing that is confirmation of conduction along the optical path; a branching unit for branching the optical signal in which the monitoring control signal is multiplexed; and a monitoring transponder for measuring and monitoring optical power of the monitoring control signal multiplexed into the optical signal branched by the branching unit, wherein the monitoring transponder for monitoring whether the monitored optical power is equal to or higher than a predetermined level indicating normality of the optical path. 2. The optical node device according to claim 1 , wherein the WSS includes an optical channel monitor for, when multiplexing the monitoring control signal with the optical signal, multiplexing the monitoring control signal including unique optical path identification (ID) information, and monitoring the optical path ID information obtained by reading and demodulating a temporal change of the optical power of the monitoring control signal multiplexed on the optical signal branched by the branching unit, and wherein the optical channel monitor is used for monitoring the normality of the optical path between the transmission transponder and the branching unit branching the optical signal based on the optical path ID information. 3. The optical node device according to claim 1 , wherein the WSS includes an input collimator to which the optical signal is input, a diffraction grating for receiving the optical signal through the input collimator, diffracting the optical signal at a different angle according to a wavelength of the optical signal, reflecting the optical signal, and demultiplexing the optical signal, a spatial light modulator for reflecting the demultiplexed optical signal and applying a voltage of the monitoring control signal to the optical signal at the time of reflection to apply intensity modulation, and an output collimator for outputting the optical signal reflected by the spatial light modulator. 4. An optical transport network system, comprising a plurality of optical node devices according to claim 1 , wherein the plurality of optical node devices are connected by the optical fiber via the branching unit. 5. The optical transport network system according to claim 4 , wherein the monitoring control signal has unique optical path ID information and is multiplexed into the optical signal to be transmitted on the optical path in each of WSSs on the optical path extended between the plurality of connected optical node devices. 6. An optical path tracing method by an optical node device, comprising: transmitting an optical signal via an optical path extended over an optical fiber, multiplexing, on the transmitted optical signal, a monitoring control signal for performing optical path tracing that is confirmation of conduction along the optical path, branching the optical signal in which the monitoring control signal is multiplexed, measuring and monitoring optical power of the monitoring control signal multiplexed into the optical signal, and monitoring whether the monitored optical power is equal to or higher than a predetermined level indicating normality of the optical path. 7. A non-transitory computer readable medium storing a program, wherein executing of the program causes a computer, using the optical node device of claim 1 , to perform operations comprising: transmitting an optical signal via an optical path extended over an optical fiber, multiplexing, on the transmitted optical signal, a monitoring control signal for performing optical path tracing that is confirmation of conduction along the optical path, branching the optical signal in which the monitoring control signal is multiplexed, measuring and monitoring optical power of the monitoring control signal multiplexed into the optical signal, and monitoring whether the monitored optical power is equal to or higher than a predetermined level indicating normality of the optical path. 8. The optical node device according to claim 2 , wherein the WSS includes an input collimator to which the optical signal is input, a diffraction grating for receiving the optical signal through the input collimator, diffracting the optical signal at a different angle according to a wavelength of the optical signal, reflecting the optical signal, and demultiplexing the optical signal, a spatial light modulator for reflecting the demultiplexed optical signal and applying a voltage of the monitoring control signal to the optical signal at the time of reflection to apply intensity modulation, and an output collimator for outputting the optical signal reflected by the spatial light modulator. 9. An optical transport network system, comprising a plurality of optical node devices according to claim 2 , wherein the plurality of optical node devices are connected by the optical fiber via the branching unit. 10. An optical transport network system, comprising a plurality of optical node devices according to claim 3 , wherein the plurality of optical node devices are connected by the optical fiber via the branching unit.