A detection apparatus and method for noise intensity and a coherent optical receiver where the detection method includes: preprocessing a received signal to obtain a pilot sequence contained in the received signal; removing a phase noise of a receiving pilot sequence by using a known transmitting pilot signal; calculating a noise power density of the receiving pilot sequence with no (or without) phase noise within a predetermined spectral width near a pilot frequency; and calculating power of a linear noise of the received signal based on a bandwidth of the received signal and the noise power density within the predetermined spectral width. Hence, linear noises and nonlinear noises may be split efficiently without introducing much complexity, and information on intensities of various noises may be obtained.

The disclosure is directed to a method and system for generating a pilot tone for an optical signal with an optical telecommunications system. The pilot tone is generated in the digital domain by modulating the data to be transmitted to a destination node within the optical telecommunications network. The modulation of the data introduces occurrence modulation to the optical signal.

The inclusion of a pilot tone as a modulation of an optical data signal reduces the optical signal to noise ratio (OSNR). Methods and apparatus for receiving an optical signal are provided that compensate for at least a portion of the pilot tone modulation to reduce the pilot tone induced OSNR penalty. An initial waveform is processed to generate a compensated waveform, the processing including dispersion compensation. An intensity waveform is calculated in accordance with the compensated waveform. The intensity waveform is processed to obtain a pilot tone frequency, a modulation depth, and a phase of the pilot tone. The compensated waveform is multiplied with a pilot tone compensation factor that is a function of the pilot tone frequency, the modulation depth, and the phase of the pilot tone to generate a modified compensated waveform. A symbol carried by the modified compensated waveform is determined.

Embodiments of this disclosure provide an apparatus and method for monitoring an optical signal to noise ratio, a receiver and a communication system. The apparatus for monitoring an optical signal to noise ratio includes extracting signals from signals obtained after an equalization processing is performed on optical signals received by a receiver, the optical signals including signals of known frequencies, and the signals extracted having the same spectral characteristics as the signals of known frequencies; correcting, according to filtering parameters used in the equalization processing, the signals extracted and outputting corrected signals; and calculating an optical signal to noise ratio according to the corrected signals. According to the embodiments of this disclosure, the optical signal to noise ratio may be calculated more accurately.

The present disclosure relates to a method, an apparatus and a system for monitoring performance of optical network equipment. The method comprises receiving an optical channel signal comprising a first pilot tone in a first spectral sub-band of the optical channel signal and a second pilot tone in a second spectral sub-band of the optical channel signal, the first and the second spectral sub-bands being on opposite sides of a reference frequency of the optical channel signal. The performance of the optical network equipment is monitored based on a power mismatch between the first and second pilot tones of the received optical channel signal. An apparatus and a system for monitoring performance of the optical network equipment are also described.

Embodiments of the present disclosure provide a monitoring apparatus for an optical signal to noise ratio, a signal transmission apparatus and a receiver. White noise power of received signals is calculated according to noise power and power of pilot signals of the received signals in different polarization states, and influence of a nonlinear noise is excluded, thereby accurately estimating an optical signal to noise ratio, for example, with a calculation process being simple and an application range being relatively wide.

A system for monitoring optical signal-to-noise ratio (OSNR) is provided. In some specific examples, the system may use a pilot tone power of a signal modulated with pilot tone to derive the pure signal power and the variance of the whole electric field to derive the total power (pure signal power plus amplified spontaneous emission (ASE) power of the signal). The ASE power can be obtained by subtracting the pure signal power from the total power (ASE+pure signal). Once the ASE power and the pure signal power are known, the OSNR can be calculated.

Embodiments of this disclosure provide an apparatus and method for monitoring a polarization dependent loss, a receiver and a communication system. The apparatus for monitoring a polarization dependent loss includes: a first processing unit configured to process received optical signals, to obtain a first correlation matrix of noise signals in the received optical signals and a second correlation matrix of second signals or other signals in the received optical signals other than first signals or spectral feature signals having predetermined spectral features; a matrix subtraction unit configured to subtract the second correlation matrix by the first correlation matrix, to obtain a third matrix; and a calculating unit configured to perform singular value decomposition on the third matrix, and calculate a polarization dependent loss according to a result of the singular value decomposition. According to the embodiments of this disclosure, the polarization dependent loss may be calculated more accurately.

Embodiments can provide spurs removal in a pilot-tone spread signal. For achieving this, at least one peak in the pilot-tone spread signal may be found. A predetermined small range of the spectra power around the at least one peak may be removed. In some situations, the removal of the spurs in the pilot-tone spread signal may result in inadvertent removal of a normal part of the pilot-tone spread signal. For addressing this, a power ratio between the spectrum of the pilot-tone spread signal before the removal and after the removal can be calculated. For accounting for the power loss due to the spurs removal, this power ratio can be applied to the pilot-tone spread signal after the removal to obtain a corrected pilot-tone spread signal.

A method for conveying information through an optical fiber link between a transmitter and a receiver of an optical communication system. The method includes generating, by the transmitter, a predetermined spectral change, and inserting the predetermined spectral change into an optical fiber link for transmission to the receiver. A detector associated with the receiver detects the predetermined spectral change in an optical signal received through the optical fiber link, and generates a detection signal in accordance with the detection result. The detector is independent of a digital signal processor of the receiver that is configured to recover data modulated on the optical signal received through the optical fiber link.