Optical communication system with monitor functions and monitoring method therefor

The invention claimed is: 1. A monitoring method for an optical communication system, comprising the steps of: emitting lightwave signals to be modulated according to a data; forming dips at transitions between temporally consecutive groups of n symbols of the lightwave signals, n representing an integer equal to or greater than 3, wherein the dips are formed at each of (n−1) first transitions of the group, no dip is formed at the n-th transition on the lightwave signals, n consecutive transitions between symbols comprise at least (n−1) dips; receiving the lightwave signals; extracting frequency components characterized by the numerical value n from received lightwave signals; and monitoring the received lightwave signals by using the frequency components. 2. The monitoring method for an optical communication system according to claim 1 , wherein the step of forming dips further comprises shaping n−2 symbols as pulses with a pulse period equal to a symbol period, shaping a rising edge of amplitude on a temporally following (n−1)-th symbol, keeping amplitude unaffected during a transition between the (n−1)-th symbol and a nth symbol, and shaping a falling edge of amplitude on the nth symbol. 3. The monitoring method for an optical communication system according to claim 1 , wherein the frequency components include a signal component with one-nth frequency of the symbol rate in the lightwave signals. 4. The monitoring method for an optical communication system according to claim 1 , wherein a numerical value of n is defined as a deferent value for each of the lightwave signals emitted by the optical communication system. 5. An optical communication system with monitor functions, comprising: an optical transmitter; containing a carver forming dips on groups of temporally consecutive n symbols, n representing an integer equal to or greater than 3, wherein (n−1) dips are formed, each dip is located at each of (n−1) first transitions between symbols, no dip is formed at the n-th transition between symbols; and an optical receiver; containing a coherent receiver receiving the lightwave signals, a processing unit extracting frequency components characterized by the numerical value of n from received lightwave signals and monitoring the received lightwave signals by using the frequency components. 6. The optical communication system with monitor functions according to claim 5 , wherein the carver shapes n−2 symbols as pulses with a pulse period equal to a symbol period, shapes a rising edge of amplitude on a temporally following (n−1)-th symbol, keeps amplitude unaffected during a transition between the (n−1)-th symbol and a nth symbol, and shapes a falling edge of amplitude on the nth symbol. 7. The optical communication system with monitor functions according to claim 5 , wherein the processing unit extracts the frequency components including a signal component with one-nth frequency of the symbol rate in the lightwave signals. 8. The optical communication system with monitor functions according to claim 5 , wherein the lightwave signals are Polarization-Division-Multiplexed Quadrature-Pphase-Shift-Keying (PDM-QPSK) signals. 9. The optical communication system with monitor functions according to claim 5 , wherein the carver comprises a clock outputting an electrical clock signal at a frequency proportional to the baud rate, a narrow pulse clock source generating a narrow pulse clock at the same frequency as the clock with duty cycle proportional to one-nth, and a modulator carving an amplitude of the input lightwave signal on the basis of outputs of the clock and the narrow pulse clock source. 10. The optical communication system with monitor functions according to claim 5 , further comprising digital to analog converters generating electrical signals on the basis of data to be modulated and on the basis of the formed dips, and a modulator carving the amplitude of the input lightwave signal on the basis of the generated electrical signal.