JP5544938B2 - Optical transmission system, optical transmission method, and optical receiver - Google Patents

Description

  The present invention relates to an optical transmission technique using optical phase modulation and demodulation.

  In recent years, commercial introduction of ultra-high-speed optical transmission systems of 40 Gbit / s or higher is newly starting to replace the current 2.5 Gbit / s and 10 Gbit / s optical transmission systems. In the ultra-high-speed optical transmission system, instead of the conventional intensity modulation (Amplitude Shift Keying) system, the adoption of a phase modulation (Phase Shift Keying) system excellent in transmission characteristics such as optical noise resistance characteristics is considered promising. Among the phase modulation schemes, differential binary phase modulation schemes (Differential (Binary) Phase Shift Keying, D (B) PSK) and differential quaternary phase modulation schemes are particularly preferred because of the balance between transmission characteristics, ease of implementation, and cost. Research and development are being promoted toward the practical application of a system such as (Differential Quadrature Phase Shift Keying, DQPSK) (for example, Patent Document 1).

  FIG. 9 is a diagram illustrating a configuration of an example of an optical transmission system using such a phase modulation method. This optical transmission system includes an optical transmission unit 501, a transmission line fiber 502, and an optical reception unit 503, and is applied to an ultrahigh-speed optical transmission system of 40 Gbit / s or more. As the light modulation method, a differential quaternary phase modulation method is used.

In FIG. 9, the optical transmission unit 501 includes a light source 511, an optical modulation unit 512, a precoder 513-1, and a precoder 513-2.
The light source 511 transmits continuous wave light (Continuous Wave light: CW light) for performing optical transmission. This oscillation light is sent to the light modulation unit 512.

  Two sets of binary electrical information signals of an I (In Phase) channel and a Q (Quadrature Phase) channel are input from the data input terminals 515 and 516 to the precoder unit 513-1 and the precoder unit 513-2. The precoder 513-1 and the precoder 513-2 perform signal conversion processing corresponding to signal conversion by differential demodulation on the input I-channel and Q-channel electrical information signals, respectively. The electrical information signal subjected to the signal conversion processing by the precoder unit 513-1 and the precoder unit 513-2 is sent to the optical modulation unit 512.

  The optical modulation unit 512 performs differential quaternary phase modulation on the continuous wave light transmitted from the light source 511 using the electrical information signals from the precoder unit 513-1 and the precoder unit 513-2, and converts the optical phase from the electrical information signal to the optical phase. Convert to modulated signal. The optical modulation unit 512 can be configured by, for example, a modulator composed of a Mach-Zehnder interferometer and a π / 2 phase shifter for making the phases of IQ optical signals orthogonal.

The transmission line fiber 502 transmits the optical phase modulation signal output from the optical transmission unit 501 to the optical reception unit 503.
The optical receiving unit 503 includes a tunable dispersion compensation (TDC) unit 531, a delay interference unit 532-1, a delay interference unit 532-2, a differential photoelectric conversion detection unit 533-1, and a differential photoelectric converter. Conversion detection unit 533-2, classifier 534-1, classifier 534-2, separation unit 535, error correction (Forward Error Correction: FEC) unit 536, dispersion compensator control unit 537, delay interference And a meter control unit 538.

  The tunable dispersion compensator 531 compensates for waveform distortion due to dispersion caused by the transmission line fiber 502. The dispersion compensator 531 is controlled by the dispersion compensator controller 537. The optical signal from the tunable dispersion compensator 531 is parallelized and sent to the delay interference units 532-1 and 532-2.

  The delay interference unit 532-1 and the delay interference unit 532-2 convert and demodulate phase modulation into intensity modulation by delay interference processing for the optical signal from the tunable dispersion compensator 531. Each of the two parallel delay interference units 532-1 and 532-2 includes a delay interferometer for one bit. In the delay interferometers of the delay interference unit 532-1 and the delay interference unit 532-2, the optical phase is controlled so that the optical phase of one arm is shifted + π / 4, −π / 4 with respect to the signal light phase. . The optical signals converted into intensity modulation by the delay interference unit 532-1 and the delay interference unit 532-2 are sent to the differential photoelectric conversion detection unit 533-1 and the differential photoelectric conversion detection unit 533-2.

  The differential photoelectric conversion detection unit 533-1 and the differential photoelectric conversion detection unit 533-2 perform differential photoelectric conversion detection on the optical signal from the delay interference unit 532, and demodulate the optical signal to the electrical information signal. The electrical information signals from the differential photoelectric conversion detection unit 533-1 and the differential photoelectric conversion detection unit 533-2 are sent to the discriminator 534-1 and the discriminator 534-2.

The discriminator 534-1 and the discriminator 534-2 discriminate and reproduce the demodulated electrical information signals of the I channel and the Q channel from the differential photoelectric conversion detection unit 533-1 and the differential photoelectric conversion detection unit 533-2. The reproduced I channel and Q channel electrical information signals are sent to the separation unit 535.
Separating section 535 performs parallel processing on the I-channel and Q-channel electrical information signals from discriminator 534-1 and discriminator 534-2. This electrical information signal is sent to the error correction unit 536. The error correction unit 536 corrects an error in the electrical information signal from the separation unit 535.

The dispersion compensator control unit 537 controls the dispersion compensation amount of the variable dispersion compensator 531 based on the number of error corrections detected by the error correction unit 536.
The delay interferometer control unit 538 controls the optical phase of the delay interference unit 532-1 and the delay interference unit 532-2 based on the number of error corrections detected by the error correction unit 536. That is, the delay interferometer control unit 538 performs control so that the number of error corrections detected by the error correction unit 536 is minimized, so that one of the two parallel delay interference units 532-1 and 532-2. Each of the bit delay interferometers controls the phase of the optical signal so that the optical phase of one arm is shifted by + π / 4 and −π / 4 with respect to the signal optical phase.

  As described above, the tunable dispersion compensator 531 is provided in the optical receiver 503 of the optical transmission system of the phase modulation system. An optical signal having a transmission rate of 40 Gbit / s is strongly affected by waveform distortion due to dispersion in proportion to the square of the transmission rate, as compared to a 10 Gbit / s optical signal of the same modulation method.

  FIG. 10 is a schematic diagram showing the relationship between the chromatic dispersion amount and the bit error rate. In FIG. 10, the horizontal axis indicates the amount of chromatic dispersion, and the vertical axis indicates the bit error rate. In FIG. 10, a curve A1 shows the characteristics in the case of NRZ (Non Return to Zero) modulation scheme at 10 Gbit / s, and a curve A2 shows the characteristics in the case of NRZ modulation scheme at 40 Gbit / s. As indicated by a curve A1 in FIG. 10, at 10 Gbit / s, there are about 1600 ps / nm to 2000 ps / nm windows where the bit error rate is 10 −3 or less. On the other hand, as indicated by the curve A2, at 40 Gbit / s, the window where the bit error rate is 10-3 or less is about 80 to 100 ps / nm.

As shown in FIG. 10, in a 40 Gbit / s transmission system, the dispersion range (dispersion tolerance) in which a comparable signal error rate can be obtained is only about 1/16 of 10 Gbit / s. In the DQPSK modulation method, four-value information can be transmitted with one symbol, so the symbol rate of a 40 Gbit / s DQPSK modulated optical signal is 20 Gbit / s.
FIG. 11 is a graph showing the relationship between the chromatic dispersion amount and the bit error rate in the case of the NRZ modulation method and the DQPSK modulation method. For the above reasons, as shown in FIG. 11, the dispersion tolerance is improved to about ¼ of the 10 Gbit / s intensity modulated optical signal. In FIG. 11, a curve A11 shows the characteristic in the case of the 10 Gbit / s NRZ modulation method, and a curve A12 shows the characteristic in the case of the 40 Gbit / s DQPSK modulation method. As indicated by a curve A12 in FIG. 11, with 40 Gbit / s DQPSK, the window where the bit error rate is 10-3 or less is about 150 to 200 ps / nm. Therefore, the dispersion tolerance is improved as compared with the case of the NRZ modulation method.

  Thus, with the DQPSK modulation method, the dispersion tolerance is improved. However, in a 40 Gbit / s transmission system, the dispersion tolerance is small compared to 10 Gbit / s. Therefore, in the case where a 10 Gbit / s optical signal and a 40 Gbit / s optical signal are mixed in the same optical transmission system, a 10 Gbit / s optical signal is received by an optical receiver or the like for a 40 Gbit / s optical signal. It is necessary to perform chromatic dispersion compensation more precisely.

Therefore, in the optical receiver 503 in this optical transmission system, as shown in FIG. 9, a variable dispersion compensator 531 capable of variably controlling the dispersion compensation amount is arranged in the optical receiver 503 to optimally perform dispersion compensation. I am doing so.
Further, in an optical receiver that receives a 40 Gbit / s DQPSK modulated optical signal, in order to demodulate the dispersion-compensated differential quaternary phase modulated optical signal into an electrical information signal, two parallel delay interference units 532-1 In addition, a delay interference unit 532-2 is provided. In order to perform demodulation of DQPSK modulation, each of the two parallel delay interference units 532-1 and 532-2 includes a 1-bit delay interferometer, and the optical phase of one arm is + π with respect to the signal light phase. It is necessary to precisely control the phase of the optical signal so as to shift by / 4 and −π / 4.

  Therefore, in the optical receiving unit 503 in this optical transmission system, as shown in FIG. 9, a delay interferometer control unit 538 is arranged to control the phase of the optical signals of the delay interference units 532-1 and 532-2. I have to.

JP 2007-60583 A

  As described above, in the optical receiver 503 in the optical transmission system shown in FIG. 9, the dispersion compensation unit 531 that can variably control the dispersion compensation amount is arranged in the optical receiver 503 to optimally perform dispersion compensation. I am doing so. Also, a delay interferometer control unit 538 is arranged to control the phase of the optical signals of the delay interference units 532-1 and 532-2.

  However, in the optical receiver 503 in the optical transmission system shown in FIG. 9, the process of optimally controlling the dispersion compensation amount of the tunable dispersion compensator 531 is also performed by the optical phases of the delay interference unit 532-1 and the delay interference unit 532-2. Is also performed based on the number of error corrections detected by the error correction unit 536. When the number of error corrections in the error correction unit 536 is used as an error monitor signal for optimally controlling the dispersion compensation amount of the variable dispersion compensator 531 and the optical phase of the delay interference unit 532-1 and delay interference unit 532-2, Since the tunable dispersion compensator 531, the delay interference unit 532-1 and the delay interference unit 532-2 are changed at the same time, the change in the number of error corrections with respect to each change amount cannot be distinguished. Therefore, there arises a problem that the completion time until the dispersion compensation amount of the tunable dispersion compensator 531 and the optical phases of the delay interference unit 532-1 and the delay interference unit 532-2 are each controlled to the optimum point becomes long.

  In addition, the dispersion amount of the transmission line fiber changes due to a change in the transmission line fiber 502 due to a temperature change or the like, or a change in the transmission line fiber length due to a transmission path change or the like, or the wavelength of the transmission optical signal is switched to a different wavelength. There are cases. Therefore, the optimum dispersion compensation amount of the tunable dispersion compensator 531 in the optical receiver 503 and the optimum value of the optical phase shift amount in the delay interference unit 532-1 and the delay interference unit 532-2 may fluctuate. Regarding the dispersion compensation amount, it is necessary to take a wide variable amount of the dispersion compensator in order to cope with not only the initial startup of the apparatus but also changes during operation without replacement of parts. Therefore, there arises a problem that the completion time from the wide variable range to the optimal dispersion compensation amount is further increased.

  In view of the above problems, the present invention provides an optical transmission system, an optical receiver, and an optical transmission system that can efficiently and optimally adjust a variable dispersion compensator and a delay interferometer in an optical receiver in an optical transmission system using optical phase modulation and demodulation. An object is to provide an optical receiving method.

One aspect of the present invention is an optical transmitter that generates and transmits an optical signal subjected to differential phase modulation, and an optical receiver that receives the optical signal transmitted from the optical transmitter via a transmission line fiber. An optical transmission system comprising: a light source that transmits continuous wave light for performing optical transmission; and two sets of input binary electrical information signals, Pre-coder means for performing signal conversion processing corresponding to signal conversion by differential demodulation; and optical modulation means for performing differential phase modulation by the pre-coder means for continuous wave light from the light source. A variable dispersion compensation unit capable of varying a dispersion compensation amount with respect to a received optical signal, and delay interference processing for performing delay interference processing on two sets of optical signals output in parallel from the variable dispersion compensation unit. Means and said delay interference By performing photoelectric conversion detected for the two sets of the optical signal from the stage, and the photoelectric conversion detecting means for demodulating the two sets of electrical information signals from the differential phase modulated light, the two sets of demodulated from the photoelectric conversion detecting means and regenerating means for regenerating the electrical information signals, two sets of error correcting means for correcting the identification error of the identification reproduced signal, exclusive OR means for performing an exclusive OR operation of the two sets of regenerating signal A dispersion compensation control means for controlling a dispersion compensation amount in the variable dispersion compensation means based on a signal output from the exclusive OR means, and detecting the number of error corrections in the error correction means, and the delay Delay interferometer control means for controlling the delay interferometer of the interference means.

One aspect of the present invention is an optical transmission method including a step of transmitting a differential phase modulated optical signal and a step of receiving an optical signal transmitted from the optical transmitter via a transmission line fiber. The optical signal transmitting step includes a step of performing signal conversion processing corresponding to signal conversion by differential demodulation on each of the two sets of input binary electrical information signals, and a continuous light source. the oscillation light, comprising a step of performing differential phase modulation, the step of receiving the optical signal, and performing variable dispersion compensation on the optical signal received in the step of performing a variable dispersion compensator and performing 2 parallelized for two sets of optical signals output by the delay interference process, by performing the delay interference treated the two pairs of photoelectric conversion detection optical signal, 2 a differential phase modulated light a step of demodulating the set of electrical information signal, Exclusive OR of serial and step photoelectric conversion detection reproduces identify two sets of demodulated electrical information signal is performed, a step of correcting the identification error of the two sets of identification reproduced signal, the two sets of regenerating signal The number of error corrections in the step of calculating, the step of controlling the dispersion compensation amount of the variable dispersion compensation based on the signal output in the step of performing the exclusive OR operation, and the step of correcting the identification error Detecting and controlling a delay interferometer used in the delay interference process.

One aspect of the present invention is an optical receiver that receives a differential phase modulated optical signal transmitted through a transmission line fiber, and is capable of varying a dispersion compensation amount with respect to the received optical signal. Compensation means, delay interference means for performing delay interference processing for two sets of optical signals output in parallel from the variable dispersion compensation means, and photoelectric conversion for the two sets of optical signals from the delay interference means by detecting a photoelectric conversion detection means for demodulating the two sets of electrical information signals from the differential phase modulated light, and regenerating means for regenerating two sets of condensate demodulated electrical information signal from the photoelectric conversion detecting means and error correcting means for correcting the identification error of the two sets of identification reproduction signal, an exclusive OR means for performing an exclusive OR operation of the two sets of regenerating signal, output from the exclusive OR means Based on the signal A dispersion compensation control means for controlling the amount of dispersion compensation in the serial variable dispersion compensator, the number of error corrections from the two sets of electrical information signals detected in the error correction means, controls the delay interferometer of the delay interference means And a delay interferometer control means.

  According to the present invention, the variable dispersion compensator and the delay interference unit are controlled using separate monitor signals of the exclusive OR of the discriminator output and the number of error corrections from the error correction unit. Therefore, it is possible to perform control by operating the variable dispersion compensator and the delay interference unit at the same time, and it is possible to shorten the control time until the optimum value is reached. In addition, according to the present invention, the exclusive OR unit can operate and detect a change in time average value even under poor signal quality conditions such that frame synchronization of the error correction unit is not applied. It becomes possible to draw the control at a high speed near the center of the distributed bearing width.

1 is a block diagram showing a configuration of an optical transmission system as a first embodiment of the present invention. It is explanatory drawing of an example of the relationship between a transmission output and a reception output. It is explanatory drawing of the relationship between the transmission output when a compensation amount differs. It is a graph which shows the relationship between the average value of the output of an exclusive OR part, and the dispersion compensation amount of a variable dispersion compensation part. It is explanatory drawing of the other example of the relationship between a transmission output and a reception output. It is explanatory drawing of the relationship between the transmission output when a compensation amount differs. It is a graph which shows the relationship between the average value of the output of an exclusive OR part, and the dispersion compensation amount of a variable dispersion compensation part. It is a block diagram which shows the structure of the optical transmission system as the 2nd Embodiment of this invention. It is a block diagram of an example of the optical transmission system using a phase modulation system. It is a graph which shows the relationship between the amount of wavelength dispersion in the case of a NRZ modulation system, and a bit error rate. It is a graph which shows the relationship between the amount of chromatic dispersion in the case of a NRZ modulation system, and a DQPSK modulation system, and a bit error rate.

<First Embodiment>
FIG. 1 is a block diagram showing a configuration of an optical transmission system as a first embodiment of the present invention. This optical transmission system includes an optical transmission unit 1, a transmission line fiber 2, and an optical reception unit 3, and is applied to an ultrahigh-speed optical transmission system of 40 Gbit / s or more. As the light modulation method, a differential quaternary phase modulation method is used.

In FIG. 1, the optical transmission unit 1 includes a light source 11, an optical modulation unit 12, and precoder units 13-1 and 13-2.
The light source 11 sends out continuous wave light for optical transmission. This oscillation light is sent to the light modulator 12.

  Two sets of binary electrical information signals of the I channel and the Q channel are input from the data input terminals 15 and 16 to the precoder units 13-1 and 13-2. The precoders 13-1 and 13-2 perform signal conversion processing corresponding to signal conversion by differential demodulation on the input I-channel and Q-channel electrical information signals, respectively. The electrical information signal subjected to the signal conversion processing by the precoder units 13-1 and 13-2 is sent to the optical modulation unit 12.

  The optical modulation unit 12 performs differential quaternary phase modulation on the continuous wave light transmitted from the light source 11 using signals from the precoder units 13-1 and 13-2, and converts the electrical information signal into an optical phase modulation signal. To do. The optical modulation unit 12 can be composed of, for example, a modulator composed of a Mach-Zehnder interferometer and a π / 2 phase shifter for making the phases of IQ optical signals orthogonal.

The transmission line fiber 2 transmits the optical phase modulation signal output from the optical transmission unit 1 to the optical reception unit 3.
The optical receiver 3 includes a tunable dispersion compensator 31, delay interference units 32-1 and 32-2, differential photoelectric conversion detectors 33-1 and 33-2, and identifiers 34-1 and 34-2. , A separation unit 35, an error correction unit 36, a dispersion compensator control unit 37, a delay interferometer control unit 38, and an exclusive OR unit 39.

The variable dispersion compensator 31 compensates for waveform distortion due to dispersion caused by the transmission line fiber 2. The variable dispersion compensator 31 is controlled by a dispersion compensator controller 37. The optical signal from the tunable dispersion compensation unit 31 is parallelized and sent to the delay interference units 32-1 and 32-2.
The delay interference units 32-1 and 32-2 convert and demodulate the phase modulation into intensity modulation by delay interference processing for the optical signal from the tunable dispersion compensation unit 31. Each of the two parallel delay interfering units 32-1 and 32-2 includes a 1-bit delay interferometer. In the delay interferometers of the delay interference units 32-1 and 32-2, the optical phase is controlled so that the optical phase of one arm is shifted + π / 4, −π / 4 with respect to the signal optical phase. The optical signals converted into intensity modulation by the delay interference units 32-1 and 32-2 are sent to the differential photoelectric conversion detection units 33-1 and 33-2.

The differential photoelectric conversion detectors 33-1 and 33-2 perform differential photoelectric conversion detection on the optical signal from the delay interference unit 32, and demodulate the optical signal to the electrical information signal. The electrical information signals from the differential photoelectric conversion detection units 33-1 and 33-2 are sent to the discriminators 34-1 and 34-2.
The discriminators 34-1 and 34-2 discriminate and reproduce the demodulated electrical information signals of the I channel and the Q channel from the differential photoelectric conversion detectors 33-1 and 33-2. The reproduced I channel and Q channel electrical information signals are sent to the separation unit 35.

The demultiplexer 35 performs parallel processing on the I-channel and Q-channel electrical information signals from the discriminators 34-1 and 34-2. This electrical information signal is sent to the error correction unit 36. The error correction unit 36 corrects an error in the electrical information signal from the separation unit 35.
The exclusive OR unit 39 includes an I-channel binary electrical information signal from the differential photoelectric conversion detector 33-1 and a Q-channel binary electrical information signal from the differential photoelectric conversion detector 33-2. Find the exclusive OR with. The dispersion compensator control unit 37 controls the dispersion compensation amount of the variable dispersion compensation unit 31 based on the output signal of the exclusive OR unit 39.

  The delay interferometer control unit 38 controls the delay interference units 32-1 and 32-2 based on the number of error corrections detected by the error correction unit 36. That is, the delay interferometer control unit 38 performs control so that the number of error corrections detected by the error correction unit 36 is minimized, thereby allowing 1-bit delay interference of the two parallel delay interference units 32-1 and 32-2. The phases of the optical signals are controlled so that the optical phase of one arm is shifted by + π / 4 and −π / 4 with respect to the signal optical phase, respectively.

  As described above, in the first embodiment of the present invention, the exclusive OR unit 39 uses the I-channel electrical information signal from the differential photoelectric conversion detection unit 33-1 and the differential photoelectric conversion detection unit 33-. 2 is obtained, and the dispersion compensator control unit 37 controls the dispersion compensation amount of the variable dispersion compensator 31 based on the output signal of the exclusive OR unit 39. doing. Thereby, the waveform distortion due to dispersion caused by the transmission line fiber 2 can be optimally compensated. This will be described below.

  FIG. 2 is a diagram illustrating an example of the relationship between the transmission output and the reception output. In the optical transmission system according to the first embodiment of the present invention, when the dispersion compensation amount of the tunable dispersion compensator 31 is adjusted to the optimum value when the optical receiver is started up or the optical signal is restored, data input is performed. Signals having the same sign as shown in FIG. 2 are inputted as binary electrical information signals of I channel and Q channel inputted from terminals 15 and 16. The I channel signal and Q channel signal of the same code are subjected to signal conversion processing by the precoder units 13-1 and 13-2, subjected to differential quaternary phase modulation by the optical modulation unit 12, and transmitted from the optical transmission unit 1. Is done. In the example of FIG. 2, “1011001010...” As the I channel signal and “1011001010...” As the Q signal are differentially quadrature-phase modulated from the optical transmission unit 1 and transmitted as an optical signal. This optical signal is sent to the optical receiver 3 via the transmission line fiber 2 and received by the optical receiver 3.

  When the optical receiver 3 receives an optical signal obtained by differential quaternary phase modulation of the I channel and Q channel signals with the same code signal, and the compensation amount of the tunable dispersion compensator 31 matches the optimum value The outputs of the two parallel discriminators 34-1 and 34-2 are the same code signal. For this reason, the output of the exclusive OR unit 39 is always “0”.

  That is, when “1011001010...” As an I channel signal and “1011001010...” As a Q channel signal are transmitted after differential four-level phase modulation from the optical transmitter 1, as shown in FIG. The discriminator 34-1 outputs "1011001010 ..." as an I channel signal, and the discriminator 34-2 outputs "1011001010 ..." as a Q channel signal. When the exclusive OR of the I channel signal output from the discriminator 34-1 and the Q channel signal output from the discriminator 34-2 is obtained by the exclusive OR unit 39, it is shown in FIG. Thus, the output of the exclusive OR unit 39 is “0000000000000.

  On the other hand, when the compensation amount of the tunable dispersion compensator 31 is slightly different from the optimum value, the outputs of the two parallel discriminators 34-1 and 34-2 are not always the same code output, Random mistakes with random probability. FIG. 3 is a diagram illustrating the relationship between the transmission output and the reception output when the compensation amounts are different. For this reason, the case where the output of the discriminator 34-1 and the output of the discriminator 34-2 are not the same code output occurs, and a portion of “1” is generated in the output of the exclusive OR unit 39. Therefore, taking an average value of the output of the exclusive OR unit 39 for a certain period of time, the value is slightly larger than “0”.

  That is, in FIG. 3, “1011001010...” As the I channel signal and “1011001010...” As the Q channel signal are transmitted after differential quaternary phase modulation. Is slightly different from the optimum value. The discriminator 34-1 outputs "1011000010 ..." as the I channel signal, and the discriminator 34-2 outputs "101001010 ..." as the Q channel signal. "Is output. Here, the underlined code is incorrect. When the exclusive OR of the I channel signal output from the discriminator 34-1 and the Q channel signal output from the discriminator 34-2 is obtained by the exclusive OR unit 39, it is shown in FIG. As described above, the output of the exclusive OR unit 39 is “0001001000...”, And a portion of “1” is generated in the output of the exclusive OR unit 39.

When the compensation amount of the tunable dispersion compensator 31 is greatly different from the optimum value, the outputs of the two parallel discriminators 34-1 and 34-2 are always erroneously random, and therefore the output of the exclusive OR unit 39 is present. The average value for a certain time is “0.5”.
FIG. 4 is a graph showing the relationship between the average value of the output of the exclusive OR unit 39 and the dispersion compensation amount of the tunable dispersion compensator 31. In FIG. 4, the horizontal axis represents the dispersion compensation amount, and the vertical axis represents the average value of the output of the exclusive OR unit 39. As shown in FIG. 4, when the compensation amount of the tunable dispersion compensator 31 is set optimally, the average value of the output of the exclusive OR unit 39 is a value close to “0”. Accordingly, the dispersion compensator control unit 37 controls the compensation amount of the tunable dispersion compensation unit 31 so that the average value of the output of the exclusive OR unit 39 approaches “0”, thereby enabling optimum value control. .

  FIG. 5 is a diagram illustrating another example of the relationship between the transmission output and the reception output. FIG. 6 is a diagram illustrating an example of the relationship between the transmission output and the reception output when the compensation amounts are different. When the π / 2 phase shift in the differential quaternary phase modulation in the optical transmitter 1 is reversed, and the compensation amount of the tunable dispersion compensator 31 matches the optimum value, the two parallel discriminators 34 The outputs of -1 and 34-2 are always reverse sign signals. Therefore, the output of the exclusive OR unit 39 is always “1”. When the compensation amount of the tunable dispersion compensator 31 is slightly different from the optimum value, the outputs of the two parallel discriminators 34-1 and 34-2 are not always reverse code outputs as shown in FIG. Since there is a random error with a small probability, there is a case where the output is not the reverse sign output. In this case, the output of the exclusive OR unit 39 is “0”. Instead, it is slightly smaller than 1. When the compensation amount of the tunable dispersion compensator 31 is greatly different from the optimum value, the outputs of the two parallel discriminators 34-1 and 34-2 are always erroneously random, and therefore the output of the exclusive OR unit 39 is present. The average value for a certain time is “0.5”. This is shown in a graph in FIG. FIG. 7 is a graph showing the relationship between the average value of the output of the exclusive OR unit and the dispersion compensation amount of the variable dispersion compensator. In this case, the dispersion compensator controller 37 may control the compensation amount of the tunable dispersion compensator 31 so that the average value of the output of the exclusive OR unit 39 approaches “1”.

  As described above, in the first embodiment of the present invention, with respect to dispersion compensation, the exclusive OR unit 39 performs the I-channel signal from the differential photoelectric conversion detection unit 33-1 and the differential photoelectric conversion detection unit 33. 2 is obtained, and the dispersion compensator controller 37 controls the variable dispersion compensator 31 based on the output signal of the exclusive OR 39. On the other hand, for the optical phases of the delay interferometers of the delay interference units 32-1 and 32-2, the error correction unit 36 detects an error in the received signal, and the delay interferometer control unit 38 detects this error correction unit. Control is performed based on the number of error corrections detected in 36. Thereby, the control of the tunable dispersion compensation unit 31 and the delay interference units 32-1 and 32-2 can be independently and simultaneously controlled to the optimum value, and the dispersion compensation and the optical phase can be optimally controlled in a short time. Is possible.

<Second Embodiment>
FIG. 8 is a block diagram showing a configuration of an optical transmission system according to the second embodiment of the present invention. This optical transmission system includes an optical transmission unit 101, a transmission path fiber 102, and an optical reception unit 103.

The optical transmission unit 101 includes a light source 111, an optical modulation unit 112, and precoder units 113-1 and 113-2. This configuration is the same as the light source 11, the light modulation unit 12, and the precoder units 13-1 and 13-2 in the optical transmission unit 1 of the first embodiment.
The optical receiver 103 includes a tunable dispersion compensator 131, delay interference units 132-1 and 132-2, differential photoelectric conversion detectors 133-1 and 133-2, and identifiers 134-1 and 134-2. , A separation unit 135, an error correction unit 136, a dispersion compensator control unit 137, a delay interferometer control unit 138, and an exclusive OR unit 139. This configuration includes a variable dispersion compensation unit 31, delay interference units 32-1 and 32-2, and differential photoelectric conversion detection units 33-1 and 33-2 in the optical receiver 3 of the first embodiment. Basically the same as the discriminators 34-1 and 34-2, the separation unit 35, the error correction unit 36, the dispersion compensator control unit 37, the delay interferometer control unit 38, and the exclusive OR unit 39. It is.

  The difference between the first embodiment and the second embodiment is that the output of the discriminators 34-1 and 34-2 is supplied to the exclusive OR unit 39 in the first embodiment. Thus, in the second embodiment, the output of the port corresponding to the I channel and the Q channel in the output of the separation unit 135 obtained by developing the outputs of the discriminators 134-1 and 134-2 in parallel is output to the exclusive OR unit 139. Supply. In this example, when the separation unit 134 is a serial / parallel converter of 2: 4, the I channel signal output I-1 and the Q channel signal output Q-1 are supplied to the exclusive OR unit 139. The separation unit 135 may of course be a 2:16 serial-parallel conversion often used as a standard 300-pin MSA standard package.

In the first and second embodiments described above, the differential photoelectric conversion detectors 133-1 and 133-2 may be configured with a single input photoelectric converter.
The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1,101 ... Optical transmission part, 2,102 ... Transmission path fiber, 3,103 ... Optical reception part, 11, 111 ... Light source, 12, 112 ... Optical modulation part, 13-1, 13-2, 113-1, 113-2 ... Precoder unit 31, 131 ... Variable dispersion compensation unit 32-1, 32-2, 132-1, 132-2 ... Delay interference unit 33-1, 33-2, 133-1, 133- 2 ... differential photoelectric conversion detectors, 34-1, 34-2, 134-1, 134-2 ... discriminators, 35, 135 ... separating units, 36, 136 ... error correcting units, 37, 137 ... dispersion compensators Control unit, 38, 138 ... Delay interferometer control unit, 39 ... Exclusive OR unit

Claims (7)

An optical transmission system comprising: an optical transmitter that generates and transmits a differential phase-modulated optical signal; and an optical receiver that receives the optical signal transmitted from the optical transmitter via a transmission line fiber. Because
The optical transmitter is
A light source that emits continuous wave light for optical transmission;
Precoder means for performing signal conversion processing corresponding to signal conversion by differential demodulation for each of two sets of binary electrical information signals input;
Optical modulation means for performing differential phase modulation by the precoder means for continuous wave light from the light source,
The optical receiver is:
A variable dispersion compensation means capable of varying the dispersion compensation amount for the received optical signal;
Delay interference means for performing delay interference processing on two sets of optical signals output in parallel from the variable dispersion compensation means;
By performing photoelectric conversion detected for the two sets of optical signals from said delay interference section, and the photoelectric conversion detecting means for demodulating the two sets of electrical information signals from the differential phase modulated light,
Identification reproduction means for identifying and reproducing two sets of demodulated electrical information signals from the photoelectric conversion detection means ;
And error correcting means for correcting the identification error of the two sets of identification reproduced signal,
Exclusive OR means for performing an exclusive OR operation of the two sets of identification reproduction signals;
Dispersion compensation control means for controlling a dispersion compensation amount in the variable dispersion compensation means based on a signal output from the exclusive OR means;
An optical transmission system comprising: a delay interferometer control unit that detects a number of error corrections in the error correction unit and controls a delay interferometer of the delay interference unit. The optical transmitter gives the same signal as the two sets of binary electrical information signals,
The dispersion compensation control means adjusts the dispersion compensation amount of the variable dispersion compensation means so that the average value of the output of the exclusive OR means in the optical receiver for a certain time is close to “0” or “1”. The optical transmission system according to claim 1, wherein control is performed.   3. The optical transmission system according to claim 2, wherein the optical transmitter gives the same signal as the two sets of binary electrical information signals when the optical receiver is started up or restored.   The optical transmission system according to claim 1, wherein the exclusive OR unit performs an exclusive OR operation on the identification reproduction signal output from the identification reproduction unit.   The optical transmission system according to claim 1, wherein the exclusive OR unit performs an exclusive OR operation on the identification reproduction signals expanded in parallel. An optical transmission method comprising: transmitting a differential phase modulated optical signal; and receiving an optical signal transmitted from the optical transmitter via a transmission line fiber,
Transmitting the optical signal comprises:
A step of performing signal conversion processing corresponding to signal conversion by differential demodulation on each of two sets of input binary electrical information signals;
A step of performing differential phase modulation on continuous wave light from a light source,
Receiving the optical signal comprises:
And performing variable dispersion compensation on the received optical signal,
A step of performing a delay interference process on two sets of optical signals output in parallel by two in the step of performing variable dispersion compensation ;
By performing photoelectric conversion detection for the delayed interference treated the two pairs of optical signal, a step of demodulating the two sets of electrical information signals from the differential phase modulated light,
Identifying and reproducing the two sets of demodulated electrical information signals subjected to the photoelectric conversion detection ;
A step of correcting the identification error of the two sets of identification reproduced signal,
Performing an exclusive OR operation of the two sets of identification reproduction signals;
Controlling the dispersion compensation amount of the variable dispersion compensation based on the signal output in the step of performing the exclusive OR operation ;
Detecting the number of error corrections in the step of correcting the identification error, and controlling a delay interferometer used in the delay interference process. An optical receiver for receiving a differential phase-modulated optical signal transmitted through a transmission line fiber,
A variable dispersion compensation means capable of varying the dispersion compensation amount for the received optical signal;
Delay interference means for performing delay interference processing on two sets of optical signals output in parallel from the variable dispersion compensation means;
By performing photoelectric conversion detected for the two sets of optical signals from said delay interference section, and the photoelectric conversion detecting means for demodulating the two sets of electrical information signals from the differential phase modulated light,
And regenerating means for regenerating two sets of demodulation electrical information signal from the photoelectric conversion detecting means,
And error correcting means for correcting the identification error of the two sets of identification reproduced signal,
Exclusive OR means for performing an exclusive OR operation of the two sets of identification reproduction signals;
Dispersion compensation control means for controlling a dispersion compensation amount in the variable dispersion compensation means based on a signal output from the exclusive OR means;
An optical receiver comprising: delay interferometer control means for detecting the number of error corrections from the two sets of electrical information signals in the error correction means and controlling a delay interferometer of the delay interference means.

Images