JP4753837B2 - Digital receiver - Google Patents

Description

  The present invention relates to a digital receiver that receives a digital data signal, identifies and reproduces it, and outputs it.

  In recent years, digital communication systems have been increased in speed, and large capacity wavelength multiplexing systems having a transmission capacity of 40 Gbit / s per wavelength are being put into practical use in optical communication systems. Along with higher speeds, signal quality degradation due to lower optical signal-to-noise ratio and transmission quality degradation due to chromatic dispersion and polarization mode dispersion of transmission paths are becoming major issues, and receivers have further improved sensitivity and waveform degradation. There is a need to improve the proof stress.

  In wireless digital communication systems and recently in optical communication systems, error correction techniques are widely applied to improve sensitivity and durability. In order to perform error correction, it is necessary to transmit data obtained by performing operations on transmission data on the transmission side as redundant bits and added to the transmission data. For this reason, the transmission bit rate is increased (see Non-Patent Document 1).

  Super FEC has also proposed a method with a bit rate increase of 22% (see Non-Patent Document 2). By increasing the bit rate increase rate, the ability to improve transmission quality by error correction is improved. However, in optical communication systems that have reached 40 Gbit / s, a significant increase in bit rate is due to the operation limit of the electric circuit or transmission due to an increase in bit rate. Difficult due to characteristic deterioration.

  A receiver that improves reception sensitivity without increasing the bit rate has been proposed (see Patent Document 1). The circuit configuration is shown in FIG. This receiving apparatus includes a plurality of n discriminators having the same threshold value as one set, and k sets (n × k) discriminators 3-11 to 1n, 3-21 to 2n,. k1 to kn, and the digital data signal received by the light receiving circuit 1 is distributed by the distribution circuit 2 and input to the discriminators 3-11 to 1n, 3-21 to 2n,..., 3-k1 to kn. The control circuit 4 selects, for each set, n sets of discriminators 3-11 to 1n, 3-21 to 2n,..., 3-k1 to kn that have the same identification result, and the selection circuit 5 A selection instruction is given from the control circuit 4, and the identification result of one classifier of the set is selected and output.

In this receiving apparatus, when noises that are added to digital data signals input to the discriminators 3-11 to 1n, 3-21 to 2n,..., 3-k1 to kn and cause discrimination errors are independent of each other. Achieve significant improvements in signal quality. If the probability that one classifier is erroneous is p, the probability that all the classifiers composed of n classifiers are erroneous is ^pn , and it is determined whether n identification results match. Thus, error detection can be performed with a very high probability. When this is executed at a plurality of different threshold values, an optimum threshold value at which no error occurs at that bit can be found, and by selecting and outputting the identification result, significant signal quality improvement can be realized.

ITU-T G. 709 O. A. Sab, “FEC techniques in submarine transmission systems”, OFC'01, TuF-1 JP 2003-234699 A

In an optical communication system applied to a core network whose transmission bit rate has been increased in recent years, a DPSK (Differential Phase Shift Keying) modulation method and polarization which can be expected to improve reception sensitivity. DQPSK (Differential) with high tolerance against signal quality degradation due to mode dispersion
Quadrature Phase-Shift Keying (modulating quadrature phase-shift keying) modulation is drawing attention. In a system in which information is transmitted with these optical phases being transmitted, the phase-modulated optical signal is converted into two intensity-modulated optical signals having different logics by a Mach-Zehnder interferometer and received.

  The conventional technique for improving the reception sensitivity without increasing the bit rate is for one intensity-modulated optical signal, and two intensity-modulated lights having different logics as in the DPSK and DQPSK modulation methods. It cannot be effectively applied to signals. For example, the operation can be performed by receiving one of the two optical signals converted into the intensity modulation, but the advantage of the DPSK modulation method and the DQPSK modulation method for improving the sensitivity is impaired.

  Further, if a differential photoelectric conversion circuit is used as a receiving circuit, one electrical signal can be obtained from two optical signals converted into intensity modulation, and an improvement in sensitivity by the modulation method can be realized. However, in long-distance optical transmission systems, the main cause of noise is spontaneous emission (ASE) light from an optical amplifier, and even if one received electric signal is distributed, the independence of noise of each signal is low and high. No improvement in signal quality can be expected.

  The present invention has been made under such circumstances, and improves signal quality without increasing the bit rate in a receiver that receives two optical signals having different logics such as DPSK and DQPSK. It is an object of the present invention to provide a digital receiver that can be used.

The present invention is a digital receiver for receiving, identifying, reproducing, and outputting two digital data signals whose logics are inverted from each other. The present invention is characterized in that one of the received digital data signals is divided into two. A first distribution circuit that distributes to the first distribution circuit, a first identification circuit that identifies and reproduces one of the digital data signals output from the first distribution circuit with an identification threshold value that is higher (or lower) than a predetermined reference value; A second identification circuit for identifying and reproducing the other of the digital data signals output from the first distribution circuit with an identification threshold value lower (or higher) than a predetermined reference value; and the digital data output from the first identification circuit a second distribution circuit which distributes the signal into two, one and the digital data signal output from the second identification circuit of the digital data signal output from the second distribution circuit A first selection circuit for selecting and outputting one of a third identification circuit for identifying playing the other digital data signal said received with the same decision threshold and the second identification circuit, said second The other digital data signal output from the second distribution circuit and the digital data signal output from the third identification circuit are compared , and if the logic does not match, the digital data signal output from the second distribution circuit is selected, is in place and a first control circuit for providing a selection instruction to said first selection circuit to select the digital data signal output from the second identification circuit if Re matches logic .

  As described above, two digital data signals having different logics are compared with each other with the result identified by a threshold closer to “1” level (or “0” level) than a predetermined reference value. A threshold suitable for each bit is selected by selecting an identification result and selecting and outputting a result identified with a threshold closer to a “0” level (or “1” level) than a predetermined reference value if they match. As a result, the signal quality can be improved.

  Here, the “predetermined reference value” is, for example, a threshold usually used in a conventional digital receiver.

Alternatively, the digital receiver of the present invention is higher than one predetermined reference value of the two digital data signals received (or lower) and a fourth identification circuit for identifying reproduced by the identification threshold, the two digital data thus received A fifth discriminating circuit for discriminating and reproducing the other of the signals with an identification threshold lower (or higher) than a predetermined reference value, and a third distribution for distributing the digital data signal output from the fourth discriminating circuit into two A circuit, a signal generation circuit for generating a digital data signal of logic “0” (or “1”), one of the digital data signals output from the third distribution circuit , and the digital output from the signal generation circuit second selection circuit and the other of the digital data signal output from the third dividing circuit and the fifth identification times for selecting and outputting any one of data signals Comparing the digital data signal output from the digital data logic that selects the digital data signal output from the third dividing circuit if a mismatch is output from the signal generating circuit if Re matches logic And a second control circuit for giving a selection instruction to the second selection circuit so as to select a signal.

  As described above, two digital data signals having different logics are compared with each other with the result identified by a threshold closer to “1” level (or “0” level) than a predetermined reference value. If the identification result is selected and there is a match, there is a high probability that the bit is at the “1” level (or “0” level), so the “1” level (or “0” level) is selected and output. This operation is possible because when the bit is at the “0” level (or “1” level), it is far from the threshold and the probability of error is very small.

In addition, when the two digital data signals whose logics are inverted are input as optical signals, a first photoelectric conversion circuit that converts one of the optical signals into an electrical signal and outputs the electrical signal, and the optical signal A second photoelectric conversion circuit that converts the other into an electrical signal and outputs the electrical signal, thereby applying the digital data receiver of the present invention to a digital data signal input as an optical signal. Can do.

The digital receiver according to the present invention distributes one of the input optical signals into two when the two digital data signals whose logics are inverted are input as optical signals from the beginning. Optical signal distribution circuit, a third photoelectric conversion circuit that converts one of the optical signals output from the first optical signal distribution circuit into an electrical signal, and an output from the third photoelectric conversion circuit A sixth discriminating circuit for discriminating and reproducing the digital data signal with an discriminating threshold higher (or lower) than a predetermined reference value; a second optical signal distribution circuit for distributing the other of the inputted optical signals into two ; A fourth photoelectric conversion circuit for converting one of the optical signals output from the second optical signal distribution circuit into an electrical signal, and a digital data signal output from the fourth photoelectric conversion circuit as a predetermined reference Knowledge that is lower (or higher) than the value Seventh and identification circuit, the first optical signal other optical signal output from the distribution circuit and the second other of said two optical light signal output from the optical signal distribution circuit for regenerating the threshold A first differential photoelectric conversion circuit that converts an electric signal according to a signal level difference, and a fourth that distributes a digital data signal output from the first differential photoelectric conversion circuit into two . Distribution circuit, an eighth identification circuit for identifying and reproducing one of the digital data signals output from the fourth distribution circuit with an identification threshold value higher (or lower) than a predetermined reference value, and the fourth distribution circuit Are output from the ninth identification circuit, the eighth identification circuit, and the ninth identification circuit for identifying and reproducing the other of the digital data signals output from the digital data signal with an identification threshold value lower (or higher) than a predetermined reference value. Out of digital data signals A third selection circuit for selecting and outputting one Zureka 1 compares the digital data signal output from the sixth identification circuit and said seventh identification circuit, the eighth If they match logic A digital data signal output from the identification circuit is selected. If the logic does not match, a selection instruction is given to the third selection circuit so as to select the digital data signal output from the ninth identification circuit. And a control circuit.

  In this way, the received optical signal is branched to make a match or mismatch determination, and the electrical signal converted using the differential photoelectric conversion circuit is identified with an identification threshold value that is higher or lower than a predetermined reference value. By reproducing and selecting and outputting either one, it is possible to further improve the signal quality while maintaining the reception sensitivity improvement by DPSK or DQPSK.

Alternatively, when the two digital data signals whose logics are inverted are input as optical signals from the beginning, the digital receiver of the present invention distributes one of the input optical signals into two . Optical signal distribution circuit, a third photoelectric conversion circuit that converts one of the optical signals output from the first optical signal distribution circuit into an electrical signal, and an output from the third photoelectric conversion circuit A sixth discriminating circuit for discriminating and reproducing the digital data signal with an discriminating threshold higher (or lower) than a predetermined reference value; a second optical signal distribution circuit for distributing the other of the inputted optical signals into two ; A fourth photoelectric conversion circuit for converting one of the optical signals output from the second optical signal distribution circuit into an electrical signal, and a digital data signal output from the fourth photoelectric conversion circuit as a predetermined reference Lower (or higher) A seventh identification circuit identifying playback decision threshold, of the first optical signal output from the optical signal distribution circuit other and the second optical signal output from the optical signal distribution circuit while the two A first differential photoelectric conversion circuit that converts an electrical signal corresponding to the level difference of the optical signal, and a digital data signal output from the first differential photoelectric conversion circuit is higher than a predetermined reference value A tenth discrimination circuit for discriminating and reproducing with a (or low) discrimination threshold, a signal generation circuit for generating a digital data signal of logic “0” or “1”, and an output from the tenth discrimination circuit and the signal generation circuit a fourth selection circuit for selecting and outputting one of the digital data signal, comparing the digital data signal output from the sixth identification circuit and said seventh identification circuit, logic If they match A digital data signal output from the ten identification circuits is selected, and if the logic does not match, the fourth selection circuit gives a selection instruction to select the digital data signal output from the signal generation circuit. And a control circuit.

  As described above, two digital data signals having different logics are compared with each other with the result identified by a threshold closer to “1” level (or “0” level) than a predetermined reference value. If the identification result is selected and there is a match, there is a high probability that the bit is at the “1” level (or “0” level), so the “1” level (or “0” level) is selected and output.

Alternatively, the digital receiver of the present invention, those in the case where the logic one another than the initial two digital data signal inverted is input as an optical signal, the level of the two optical signals inputted said two optical signals A second differential photoelectric conversion circuit that converts a differential electrical signal corresponding to the difference and two single-phase electrical signals, and a single-phase digital output from the second differential photoelectric conversion circuit An eleventh discrimination circuit for discriminating and reproducing one of the data signals with an discrimination threshold higher (or lower) than a predetermined reference value, and a single-phase digital data signal output from the second differential photoelectric conversion circuit Among the two, a twelfth discriminating circuit for discriminating and reproducing the other with a discriminating threshold lower (or higher) than a predetermined reference value, and two differential digital data signals output from the second differential photoelectric conversion circuit. fifth distribution circuit for distributing the One , A thirteenth identification circuit for identifying and reproducing one of the digital data signals output from the fifth distribution circuit with an identification threshold value higher (or lower) than a predetermined reference value, and the fifth distribution circuit output from the fifth distribution circuit Are output from the fourteenth discriminating circuit for discriminating and reproducing the other digital data signal with a discrimination threshold lower (or higher) than a predetermined reference value, the thirteenth discriminating circuit, and the fourteenth discriminating circuit. comparing the fifth selection circuit for selecting and outputting one of the digital data signals, a digital data signal output from the eleventh identification circuit and the twelfth identification circuit, logic The digital data signal output from the thirteenth identification circuit is selected if they match, and the digital data signal output from the fourteenth identification circuit is selected if the logic does not match. Characterized in that a fifth control circuit for providing a selection instruction to the selection circuit.

  As described above, if a differential reception type photoelectric conversion circuit having two single-phase outputs and one differential output is used as the photoelectric conversion circuit, the signal processing of the present invention can be performed by one photoelectric conversion circuit. It becomes.

Alternatively, the digital receiver of the present invention, those in the case where the logic one another than the initial two digital data signal inverted is input as an optical signal, the level of the two optical signals inputted said two optical signals A second differential photoelectric conversion circuit that converts a differential electrical signal corresponding to the difference and two single-phase electrical signals, and a single-phase digital output from the second differential photoelectric conversion circuit An eleventh discrimination circuit for discriminating and reproducing one of the data signals with an discrimination threshold higher (or lower) than a predetermined reference value, and a single-phase digital data signal output from the second differential photoelectric conversion circuit And the other of the two is used with a discrimination threshold lower than (or higher than) a predetermined reference value, and a differential digital data signal output from the second differential photoelectric conversion circuit is predetermined. Higher than the baseline value (or B) a fifteenth identification circuit identifying playback decision threshold, a logic "0" (or "1" and the signal generating circuit for generating a digital data signal), the fifteenth identification circuit and said signal generating circuit comparing the digital data signal output and a sixth selection circuit for selecting and outputting one from the eleventh identification circuit and the twelfth identification circuit of the digital data signal output from the and, logic selects the digital data signal outputted from the identification circuit of the fifteenth if disagreement, the first to select a digital data signal logic is output from the signal generating circuit if Re matches And a sixth control circuit for giving a selection instruction to the six selection circuits.

  Thus, one of the digital data signals selected by the selection circuit can be set to a fixed “0” level (or “1” level).

  The optical signal is, for example, an optical signal obtained by converting DPSK light or DQPSK into intensity-modulated light using a Mach-Zehnder interferometer.

  The first to sixth control circuits comprise means for inverting the logic of one of the two digital data signals input to the first to sixth control circuits, and the first to sixth control circuits are configured to match the comparison results or The selection instruction given to the first to sixth selection circuits in the case of mismatching may be a selection instruction in which the selection direction is reversed.

  According to the present invention, signal quality can be improved without increasing the bit rate in a receiver that receives two optical signals having different logics such as DPSK and DQPSK.

(First embodiment)
A digital receiver according to the first embodiment will be described with reference to FIGS. FIG. 2 is a diagram illustrating a block configuration of the digital receiver according to the first embodiment. In a digital receiver which receives two digital data signals whose logics are inverted to each other, identifies and reproduces them, and outputs them, a distribution circuit 10-1 for distributing one of the received digital data signals and a distribution circuit 10-1 One of the two digital data signals is identified and reproduced with an identification threshold value that is higher ((shown as +)) (or lower) than a predetermined reference value, and the other is lower than a predetermined reference value ((− ) And an illustration) (or higher) an identification circuit 20-2 that performs identification and reproduction with an identification threshold, a distribution circuit 10-2 that distributes a digital data signal output from the identification circuit 20-1, a distribution circuit 10-2, and an identification A selection circuit 30-1 that selects and outputs one of the digital data signals output from the circuit 20-2, and the other of the received digital data signals is an identification circuit 20- The identification circuit 20-3 that performs identification and reproduction with the same identification threshold as those of the distribution circuit 10-2 and the digital data signal output from the identification circuit 20-3 are compared and output from the distribution circuit 10-2 if the logic does not match. And a control circuit 40-1 for controlling the selection circuit 30-1 to select the digital data signal output from the identification circuit 20-3 if the logic is the same.

Next, the operation of the digital receiver of the first embodiment will be described with reference to FIGS. FIG. 3 shows the frequency distribution of received signals, and represents the setting of an identification threshold value as a predetermined reference value. Hereinafter, the identification threshold value as the predetermined reference value is referred to as a normal identification threshold value. In FIG. 3, the horizontal axis represents signal amplitude and the vertical axis represents frequency. When the identification threshold value V _th is set as shown in FIG. 3, the probability P ₁ that the region (shaded area) where the signal amplitude is lower than V _th in the frequency distribution of the signal “1” erroneously changes “1” to “0”. is there. Similarly, the probability P ₀ that “0” is mistaken as “1” is a region (vertical line area) in which the signal amplitude is higher than V _th in the frequency distribution of the signal “0”. Therefore, the error rate P generated in the identification circuit is
P = P ₀ + P ₁
It becomes.

Normally, V _th is selected so that the error rate P is minimized, and the frequency distributions of the “0” level and the “1” level overlap each other. However, in the present invention, the discrimination threshold is set higher (or lower) than the normal discrimination threshold that minimizes the error rate in one discrimination circuit.

FIG. 4 shows a waveform example and frequency distribution example of the received signal in the differential reception. In the waveform examples, “x” indicates an identification level and timing closer to “1” level than usual, and “☆” indicates an identification level and timing closer to “0” level than usual. Further, V _{th +} and V _th− in the frequency distribution indicate threshold _values higher than normal and threshold _values lower than normal. The received signal is distorted from an ideal signal waveform due to noise or waveform degradation in the transmission path.

Here, when the operation is performed by setting the identification threshold value closer to the “1” level than the normal level, the identification threshold value is separated from the frequency distribution of the “0” level, and “0” is changed to “1”. The error probability P ₀ is very small. On the other hand, the probability P ₁ that “1” is mistaken as “0” increases. If the noises of the two received signals are independent, it is highly possible that “1” is mistaken as “0” when the results of the two discriminating circuits coincide with each other as shown in the figure.

Therefore, an error can be avoided by selecting an identification result of the identification threshold “☆” that is closer to the “0” level than usual. However, if two received signals are erroneous at the same time, the error cannot be detected. Even if the threshold value is closer to the “0” level than usual, if “1” is mistaken as “0”, the output result is erroneous. However, the probability of erroneously setting “1” to “0” at a threshold value closer to the “0” level than usual is very small and can be ignored. Therefore, the error rate P ′ of this receiver is
P '= P ₁ ' ² + P ₀ '
It becomes.

Here, P ₁ ′ is a threshold that is closer to the “1” level than normal and is a probability that “1” is mistaken as “0”, and P ₀ ′ is “0” that is closer to the “1” level than normal. This is the probability of mistaken “1”. If the probability of mistakes in two input signals at the same time is higher than the original error rate, the error rate improvement effect cannot be obtained. Therefore, the operating condition of the present invention is that the error rate P ₁ ′ is P ₁ ′ <P ^1/2.
The operation is performed with an identification threshold value that is a region of

When the identification threshold is made closer to the “1” level than usual, the probability of erroneously setting “0” to “1” decreases, and the overall error rate decreases. Furthermore, when the discrimination threshold is brought closer to the “1” level, P ₁ ′ increases, and the probability of mistakes occurring simultaneously with two input signals increases, increasing the overall error rate. Therefore, there is an optimum discrimination threshold. .

(Second embodiment)
A digital receiver according to the second embodiment is shown in FIG. FIG. 5 is a diagram showing a block configuration of a digital receiver according to the second embodiment. Here, the receiver configuration when the received signal is an optical signal is shown, and the optical signal is converted into an electrical signal by the photoelectric conversion circuits 50-1 and 50-2, and the signal processing of the first embodiment is performed. To do.

(Third embodiment)
A digital receiver according to the third embodiment is shown in FIG. FIG. 6 is a diagram showing a block configuration of a digital receiver according to the third embodiment. Here, the difference from the first embodiment is that one of the inputs of the selection circuit 30-2 is changed to a signal generation circuit 60 that outputs a fixed signal of logic “1” (or “0”). When the coincidence or non-coincidence determination performed in the control circuit 40-2 is coincident, the logic of the bit is highly likely to be “1” (or “0”). The signal “)” may be selected and output. With this configuration, the number of identification circuits can be reduced.

(Fourth embodiment)
A digital receiver according to the fourth embodiment is shown in FIG. FIG. 7 is a diagram showing a block configuration of a digital receiver according to the fourth embodiment. Here, the receiver configuration when the received signal is an optical signal is shown. The optical signal is converted into an electrical signal by the photoelectric conversion circuits 50-1 and 50-2, and the signal processing of the third embodiment is performed. carry out.

(Fifth embodiment)
A digital receiver according to the fifth embodiment is shown in FIG. FIG. 8 is a diagram showing a block configuration of a digital receiver according to the fifth embodiment. Here, the received optical signal is distributed by the optical signal distribution circuits 70-1 and 70-2, and processing is performed separately for the control system and the main signal system. One is discriminated and reproduced by the two discriminating circuits 20-6 and 20-7 having different discriminating thresholds after the photoelectric conversion by the photoelectric converting circuits 50-3 and 50-4, and the matching or mismatching judgment is made by the control circuit 40-3. Done. The other is converted into an electric signal by the differential photoelectric conversion circuit 80-1, and distributed to the two identification circuits 20-8 and 20-9 having different identification threshold values by the distribution circuit 10-4, and then identified and reproduced. Thus, one of the identification results is selected by the selection circuit 30-3. It is possible to obtain both improvement in reception sensitivity by using the differential photoelectric conversion circuit 80-1 and improvement in transmission quality by signal processing.

(Sixth embodiment)
FIG. 9 shows a digital receiver according to the sixth embodiment. FIG. 9 is a diagram showing a block configuration of a digital receiver according to the sixth embodiment. Here, the fifth embodiment is different from the fifth embodiment in that one of the two identification circuits selected by the selection circuit 30-4 is supplied to the signal generation circuit 60 that outputs a fixed signal of logic “1” (or “0”). The difference is that the identification circuit 20-10 and the signal generation circuit 60 are connected to the input side of the selection circuit 30-4. When the coincidence or non-coincidence determination performed in the control circuit 40-4 is coincident, the logic of the bit is highly likely to be “1” (or “0”), and therefore the logic “1” (or “ 0 ") signal may be selected and output. With this configuration, the number of identification circuits can be reduced.

(Seventh embodiment)
FIG. 10 shows a digital receiver according to the seventh embodiment. FIG. 10 is a diagram showing a block configuration of a digital receiver according to the seventh embodiment. A configuration in which photoelectric conversion is performed by a differential photoelectric conversion circuit 80-2 having two single-phase outputs and one differential output is shown. A detailed configuration example of the differential photoelectric conversion circuit 80-2 is shown in FIG. With this configuration, signal processing can be performed by one differential photoelectric conversion circuit 80-2, and cost reduction can be achieved.

(Eighth embodiment)
The digital receiver according to the eighth embodiment is shown in FIG. FIG. 12 is a diagram showing a block configuration of a digital receiver according to the eighth embodiment. Here, the difference from the seventh embodiment is that one of the two identification circuits selected by the selection circuit 30-6 is connected to a signal generation circuit 60 that outputs a fixed signal of logic “1” (or “0”). The difference is that an identification circuit 20-15 and a signal generation circuit 60 are connected to the input side of the selection circuit 30-6. When the coincidence or non-coincidence determination performed in the control circuit 40-6 is coincident, the logic of the bit is highly likely to be “1” (or “0”), and therefore the logic “1” (or “ 0 ") signal may be selected and output. With this configuration, the number of identification circuits can be reduced.

  The operation of the configuration using the differential photoelectric conversion circuit 80-2, in which the received signal is a DPSK (or DQPSK) modulated signal, will be described with reference to FIG. 13 and FIG. FIG. 13 shows an operation of converting a DPSK (or DQPSK) modulated optical signal into two intensity modulated lights whose logics are inverted from each other by a Mach-Zehnder interferometer (MZI). The DPSK (or DQPSK) optical signal is input to MZI, divided according to the transmission characteristics of Port A and Port B (the lower side in the figure), and two intensity-modulated lights whose logics are inverted from each other are output. Since the spectrum of these two optical signals is separated by MZI, the frequency of ASE light, which is the main noise in an optical transmission system using an optical amplifier, is different and becomes independent noise. In the present invention, signal quality can be improved by receiving and processing these two intensity-modulated lights.

FIG. 14 shows a signal waveform and a signal level distribution in a configuration using a differential photoelectric conversion circuit. The gray portion of the signal waveform schematically represents a state where the signal level distribution is widened by noise. In the figure, “x” and “☆” respectively represent an identification threshold closer to the “1” level than normal and an identification threshold closer to the “0” level than normal. On the other hand, V _{th +} and V _th− of the level distribution on the right side of the figure indicate an identification threshold higher than normal and an identification threshold lower than normal, respectively.

  In an optical transmission system using an optical amplifier, the main noise is ASE light of the optical amplifier and beat noise of the optical signal, which mainly appears at a high level of the signal light intensity. Therefore, the noise of “1” level and “0” level is dominant in the output signals of Port A and Port B whose logic is inverted. In the differentially received signal, the amplitude is doubled, and the noise is on both the “0” level and the “1” level. The two signals are discriminated and reproduced by the discriminating threshold value that is closer to the “1” level than usual, and the logical coincidence or inconsistency is determined. Since the logic is inverted, if the identification results do not match, it is determined that both have not caused an identification error, and the differentially received signal is identified and reproduced with an identification threshold closer to “1” level than usual. Output.

  If the identification results match, it can be determined that either has caused an identification error. In this case, since the identification threshold is brought close to the “1” level, there is a high possibility that the “1” level is mistaken as the “0” level. For this reason, the result of discriminating and reproducing the differentially received signal with the discrimination threshold closer to “0” level than normal is output.

  By such an operation, it is possible to output a signal identified with an optimum identification threshold for each bit of the received signal, and it is possible to improve the signal quality.

  The logic of either one of the two digital data signals input to the control circuits 40-1 to 6 in the first to eighth embodiments is inverted, and the control circuits 40-1 to 40-6 The selection instruction given to the selection circuits 30-1 to 6 in the case of coincidence or non-coincidence can be a selection instruction in which the selection direction is reversed.

  According to the present invention, in a digital receiver that receives two optical signals having different logics such as DPSK and DQPSK, the signal quality can be improved without increasing the bit rate, so that the application range of DPSK and DQPSK can be improved. Can contribute to expansion.

The figure which shows the structural example of a prior art. The block block diagram of the digital receiver of 1st embodiment. The figure which shows frequency distribution of a received signal. The figure which shows the waveform example and frequency distribution example of the received signal in differential reception. The block block diagram of the digital receiver of 2nd embodiment. The block block diagram of the digital receiver of 3rd embodiment. The block block diagram of the digital receiver of 4th embodiment. The block block diagram of the digital receiver of 5th embodiment. The block block diagram of the digital receiver of 6th Embodiment. The block block diagram of the digital receiver of 7th Embodiment. The figure which shows the detailed structural example of a differential photoelectric conversion circuit. The block block diagram of the digital receiver of 8th Embodiment. The figure which shows the operation example at the time of receiving the DPSK modulation signal of the digital receiver of 8th Embodiment. The figure which shows the operation example in the structure using the differential photoelectric conversion circuit of the digital receiver of 8th Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Light reception circuit 2, 10-1 to 10-5 Distribution circuit 3-11 to 3-kn Discriminator 4 Control circuit 5, 30-1 to 30-6 Selection circuit 20-1 to 20-15 Identification circuit 40-1 40-6 Control Circuits 50-1 to 50-4 Photoelectric Conversion Circuit 60 Signal Generation Circuits 70-1, 70-2 Optical Signal Distribution Circuits 80-1, 80-2 Differential Photoelectric Conversion Circuit

Claims (9)

In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
A first distribution circuit for distributing one of the received digital data signals into two ;
A first identification circuit that identifies and reproduces one of the digital data signals output from the first distribution circuit with an identification threshold higher (or lower) than a predetermined reference value;
A second identification circuit for identifying and reproducing the other of the digital data signals output from the first distribution circuit with an identification threshold value lower (or higher) than a predetermined reference value;
A second distribution circuit for distributing the digital data signal output from the first identification circuit into two ;
A first selection circuit that selects and outputs one of the digital data signals output from the second distribution circuit and the digital data signals output from the second identification circuit;
A third identification circuit that identifies and reproduces the other of the received digital data signals with the same identification threshold as the second identification circuit;
The other of the digital data signals output from the second distribution circuit and the digital data signal output from the third identification circuit are compared , and if the logic does not match, the digital output from the second distribution circuit select the data signal, and a first control circuit for providing a selection instruction to said first selection circuit to select the digital data signal output from the second identification circuit if Re matches logic A digital receiver characterized by that. In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
A fourth discriminating circuit for discriminating and reproducing one of the two received digital data signals with an discrimination threshold higher (or lower) than a predetermined reference value;
A fifth discriminating circuit for discriminating and reproducing the other of the received two digital data signals with a discriminating threshold lower (or higher) than a predetermined reference value;
A third distribution circuit for distributing the digital data signal output from the fourth identification circuit into two ;
A signal generation circuit for generating a digital data signal of logic “0” (or “1”);
A second selection circuit that selects and outputs one of the digital data signals output from the third distribution circuit and the digital data signal output from the signal generation circuit;
The other of the digital data signals output from the third distribution circuit and the digital data signal output from the fifth identification circuit are compared , and if the logic does not match, the digital output from the third distribution circuit select the data signals, further comprising a second control circuit for providing a selection instruction to the second selection circuit to select the digital data signal logic is output from the signal generating circuit if Re matches Features digital receiver. The two digital data signals whose logics are inverted are input as optical signals,
A first photoelectric conversion circuit that converts one of the optical signals into an electrical signal and outputs the electrical signal;
The digital receiver of Claim 1 or 2 provided with the 2nd photoelectric conversion circuit which converts the other of the said optical signal into an electrical signal, and outputs it. In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
The two digital data signals whose logics are inverted are input as optical signals,
A first optical signal distribution circuit that distributes one of the input optical signals into two ;
A third photoelectric conversion circuit that converts one of the optical signals output from the first optical signal distribution circuit into an electrical signal;
A sixth identification circuit for identifying and reproducing the digital data signal output from the third photoelectric conversion circuit with an identification threshold value higher (or lower) than a predetermined reference value;
A second optical signal distribution circuit for distributing the other of the inputted optical signals into two ;
A fourth photoelectric conversion circuit that converts one of the optical signals output from the second optical signal distribution circuit into an electrical signal;
A seventh identification circuit for identifying and reproducing the digital data signal output from the fourth photoelectric conversion circuit with an identification threshold lower (or higher) than a predetermined reference value;
The other of the optical signals output from the first optical signal distribution circuit and the other of the optical signals output from the second optical signal distribution circuit are converted into an electrical signal corresponding to the level difference between the two optical signals. A first differential photoelectric conversion circuit;
A fourth distribution circuit for distributing the digital data signal output from the first differential photoelectric conversion circuit into two ;
An eighth discriminating circuit for discriminating and reproducing one of the digital data signals output from the fourth distribution circuit with a discriminating threshold higher (or lower) than a predetermined reference value;
A ninth identification circuit for identifying and reproducing the other of the digital data signals output from the fourth distribution circuit with an identification threshold value lower (or higher) than a predetermined reference value;
A third selection circuit for selecting and outputting one of the digital data signal output from the eighth identification circuit and said ninth identification circuit,
The digital data signals output from the sixth identification circuit and the seventh identification circuit are compared, and if the logic matches, the digital data signal output from the eighth identification circuit is selected, and the logic does not match And a third control circuit for giving a selection instruction to the third selection circuit so as to select the digital data signal output from the ninth identification circuit, if any. In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
The two digital data signals whose logics are inverted are input as optical signals,
A first optical signal distribution circuit that distributes one of the input optical signals into two ;
A third photoelectric conversion circuit that converts one of the optical signals output from the first optical signal distribution circuit into an electrical signal;
A sixth identification circuit for identifying and reproducing the digital data signal output from the third photoelectric conversion circuit with an identification threshold value higher (or lower) than a predetermined reference value;
A second optical signal distribution circuit for distributing the other of the inputted optical signals into two ;
A fourth photoelectric conversion circuit that converts one of the optical signals output from the second optical signal distribution circuit into an electrical signal;
A seventh identification circuit for identifying and reproducing the digital data signal output from the fourth photoelectric conversion circuit with an identification threshold lower (or higher) than a predetermined reference value;
The other of the optical signals output from the first optical signal distribution circuit and the other of the optical signals output from the second optical signal distribution circuit are converted into an electrical signal corresponding to the level difference between the two optical signals. A first differential photoelectric conversion circuit;
A tenth discriminating circuit for discriminating and reproducing the digital data signal output from the first differential photoelectric conversion circuit with a discriminating threshold higher (or lower) than a predetermined reference value;
A signal generation circuit for generating a digital data signal of logic “0” or “1”;
A fourth selection circuit for selecting and outputting one of the digital data signals output from the tenth identification circuit and the signal generation circuit;
The digital data signals output from the sixth identification circuit and the seventh identification circuit are compared, and if the logic matches, the digital data signal output from the tenth identification circuit is selected, and the logic does not match And a fourth control circuit for giving a selection instruction to the fourth selection circuit so as to select the digital data signal output from the signal generation circuit, if any. In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
The two digital data signals whose logics are inverted are input as optical signals,
A second differential photoelectric conversion circuit that converts two input optical signals into a differential electrical signal corresponding to a level difference between the two optical signals and two single-phase electrical signals;
An eleventh discrimination circuit for discriminating and reproducing one of the single-phase digital data signals output from the second differential photoelectric conversion circuit with a discrimination threshold higher (or lower) than a predetermined reference value;
A twelfth discrimination circuit for discriminating and reproducing the other of the single-phase digital data signals output from the second differential photoelectric conversion circuit with a discrimination threshold lower (or higher) than a predetermined reference value;
A fifth distribution circuit for distributing the differential digital data signal output from the second differential photoelectric conversion circuit into two ;
A thirteenth discrimination circuit for discriminating and reproducing one of the digital data signals output from the fifth distribution circuit with an discrimination threshold higher (or lower) than a predetermined reference value;
A fourteenth discriminating circuit for discriminating and reproducing the other of the digital data signals output from the fifth distribution circuit with a discriminating threshold lower (or higher) than a predetermined reference value;
A fifth selection circuit for selecting and outputting one of the digital data signal output from the thirteenth identification circuit and the fourteenth identification circuit,
The digital data signals output from the eleventh identification circuit and the twelfth identification circuit are compared, and if the logic matches, the digital data signal output from the thirteenth identification circuit is selected, and the logic And a fifth control circuit for giving a selection instruction to the fifth selection circuit so as to select the digital data signal output from the fourteenth identification circuit if the two are inconsistent. Receiver. In a digital receiver that receives, regenerates and outputs two digital data signals whose logics are inverted from each other,
The two digital data signals whose logics are inverted are input as optical signals,
A second differential photoelectric conversion circuit that converts two input optical signals into a differential electrical signal corresponding to a level difference between the two optical signals and two single-phase electrical signals;
An eleventh discrimination circuit for discriminating and reproducing one of the single-phase digital data signals output from the second differential photoelectric conversion circuit with a discrimination threshold higher (or lower) than a predetermined reference value;
A twelfth discrimination circuit for discriminating and reproducing the other of the single-phase digital data signals output from the second differential photoelectric conversion circuit with a discrimination threshold lower (or higher) than a predetermined reference value;
A fifteenth discrimination circuit for discriminating and reproducing the differential digital data signal output from the second differential photoelectric conversion circuit with an discrimination threshold higher (or lower) than a predetermined reference value;
A signal generation circuit for generating a digital data signal of logic “0” (or “1”);
A sixth selection circuit for selecting and outputting one of the digital data signal output from the fifteenth identification circuit and said signal generating circuit,
Compare the digital data signals output from the eleventh identification circuit and the twelfth identification circuit, if the logic does not match, select the digital data signal output from the fifteenth identification circuit, digital receiver, characterized in that a sixth control circuit for providing a selection instruction to the sixth selection circuit to select the digital data signal logic is output from the signal generating circuit if Re matches . The optical signal is converted from differential phase shift keying (DPSK) light or differential quadrature phase shift keying (DQPSK) to intensity modulated light by a Mach-Zehnder interferometer. digital receiver according to any one of claims 3 to 7 is converted optical signal. Means for inverting the logic of one of the two digital data signals input to the first to sixth control circuits;
9. The first to sixth control circuits, wherein a selection instruction given to the first to sixth selection circuits when a comparison result matches or does not match is a selection instruction in which a selection direction is reversed. The digital receiver in any one.

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