Optical receiver that has function to detect signal superimposed on optical signal and method for receiving optical signal

What is claimed is: 1. An optical receiver that receives a wavelength multiplexed optical signal including a plurality of wavelength channels, a superimposition signal being superimposed by frequency modulation on each of the wavelength channels, the optical receiver comprising: an optical filter that filters the wavelength multiplexed optical signal; a photo detector that generates an intensity signal representing a change in an intensity of output light of the optical filter; an amplitude detector that detects an amplitude of the intensity signal output from the photo detector; a signal detector that detects, according to the intensity signal generated by the photo detector, a superimposition signal superimposed on a specified wavelength channel; an error detector that detects an error in the superimposition signal detected by the signal detector; and a filter controller that controls a wavelength of a transmission band of the optical filter according to the amplitude detected by the amplitude detector and the number of errors detected by the error detector, wherein the filter controller controls the wavelength of the transmission band of the optical filter so that the amplitude of the intensity signal detected by the amplitude detector increases, and then controls the wavelength of the transmission band of the optical filter so that the number of errors in the superimposition signal detected by the signal detector is reduced. 2. The optical receiver according to claim 1 , wherein the frequency modulated signal includes an error detection code, and the error detector detects an error in the superimposition signal detected by the signal detector using the error detection code. 3. The optical receiver according to claim 1 , wherein the filter controller controls a center of the transmission band of the optical filter at a first wavelength so that the amplitude of the intensity signal reaches a peak, and then controls the center of the transmission band of the optical filter at a second wavelength so that the number of errors in the superimposition signal detected by the signal detector becomes zero. 4. The optical receiver according to claim 3 , further comprising an association unit that associates data that is represented by the superimposition signal detected by the signal detector with a wavelength channel adjacently arranged on the short wavelength side of the second wavelength when the second wavelength is shorter than the first wavelength, and that associates the data with a wavelength channel adjacently arranged on the long wavelength side of the second wavelength when the second wavelength is longer than the first wavelength. 5. The optical receiver according to claim 3 , further comprising: a phase detector that decides whether the superimposition signal detected by the signal detector is inverted with respect to a superimposition signal transmitted from a transmitter of the wavelength multiplexed optical signal; and an association unit that associates data that is represented by the superimposition signal detected by the signal detector with one of a first wavelength channel adjacently arranged on the short wavelength side of the second wavelength and a second wavelength channel adjacently arranged on the long wavelength side of the second wavelength when the superimposition signal detected by the signal detector is not inverted, and that associates the data with the other of the first wavelength channel and the second wavelength channel when the superimposition signal detected by the signal detector is inverted. 6. A method for receiving a wavelength multiplexed optical signal including a plurality of wavelength channels, a superimposition signal being superimposed by frequency modulation on each of the wavelength channels, the method comprising: filtering the wavelength multiplexed optical signal using an optical filter; generating, using a photo detector, an intensity signal representing a change in an intensity of output light of the optical filter; detecting, using an amplitude detector, an amplitude of the intensity signal output from the photo detector; detecting, according to the intensity signal, a superimposition signal superimposed on a specified wavelength channel; detecting, using an error detector, an error in the superimposition signal; receiving an output signal of the amplitude detector and performing a feedback control to control a center of the transmission band of the optical filter at a first wavelength so that the amplitude of the intensity signal increases; receiving an output signal of the error detector and performing a feedback control to control the center of the transmission band of the optical filter at a second wavelength so that the number of errors in the superimposition signal is reduced, after the center of the transmission band of the optical filter is controlled at the first wavelength; and detecting, according to the intensity signal, the superimposition signal superimposed on the specified wavelength channel when the center of the transmission band of the optical filter is controlled at the second wavelength.