JP2004349798A - Receiving circuit and digital transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a receiving circuit capable of improving a bit error by limiting a transmission bit rate and without increasing it. <P>SOLUTION: An input optical signal is inputted into identification circuits 61-1 to 6k-n and to adding circuits 7-1 to 7-k via an optical distributor 2, optical receiving circuits 4-1 to 4-n, and distributing circuits 5-1 to 5-n. The identification circuits 61-1 to 61-n have the same threshold 1, the identification circuits 62-1 to 62-n have the same threshold 2, and the identification circuits 6k-1 to 6k-n have the same threshold k. The adding circuits 7-1 to 7-k execute analog sum of each output from n pieces of the distribution circuits 5-1 to 5-n. K pieces of identification circuits 8-1 to 8-k use outputs of the adding circuits 7-1 to 7-k as inputs, respectively, and have first to kth thresholds. A control circuit 9 inputs identification results of the first-kth sets of the identification circuits, selects a set in which the number of identification circuits having the same identification result is the largest, and outputs its selecting result. A selecting circuit 10 selects any one of outputs of the k pieces of identification circuits 8-1 to 8-k and outputs the selected output. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a digital transmission system mainly using an optical fiber, and more particularly to a reception circuit for improving the quality of received data and a digital transmission system using the same.
[0002]
[Prior art]
Transmission systems using optical fibers have been introduced worldwide, and a single wavelength has a capacity as high as 40 Gbit / s. The method that is usually used is the simplest method called IM-DD (Intensity Modulation-Direct Detection). The transmitter ON / OFF-modulates the light intensity according to the digital signal “0” or “1”. On the other hand, the receiver directly converts the light intensity into an electric signal by the photoelectric conversion effect, and then determines whether it is “0” or “1” based on a certain threshold (identification reproduction). Here, the threshold value is usually fixed and operated (this identification method is called a hard decision). Regarding the determination of the threshold value, there are a method of optimizing without connecting an optical fiber and a method of optimizing with connecting an optical fiber. For commercial systems, the former is usually adopted because of its wide range of application.
[0003]
After the optical fiber transmission, erroneous recognition of "0" and "1", that is, a bit error occurs when performing the above-described discrimination and reproduction due to chromatic dispersion of the optical fiber, spontaneous emission optical noise of the optical amplifier, and the like. A bit error is a problem when high-speed transmission as high as 40 Gbit / s limits the transmission distance. There are roughly two methods for solving this misidentification problem. One is error correction (Forward Error Correction: FEC), and the other is threshold feedback equalization (DFE).
[0004]
Error correction (FEC) techniques are widely used to overcome the problem of bit errors [ITU-Trecommendation G. 975]. Here, the threshold value of the identification circuit is usually fixed. In the error correction, information to be transmitted is subjected to a digital operation, and the resulting redundant bits are transmitted. Therefore, the bit rate usually increases. The received signal is operated again, the result is compared with the transmitted redundant bits, an error position is detected, and the result is corrected by exclusive OR. Although FEC is effective for random errors, it is not very effective for burst errors in fading phenomena such as polarization mode dispersion.
[0005]
As means for overcoming fading phenomena such as polarization mode dispersion, a threshold feedback equalization method (Decision Feedback Equalization: DFE) has been proposed (see Non-Patent Document 1). This method is a method in which the threshold value of the discriminating circuit is made variable, or a plurality of discriminating circuits in which a number of threshold values are set are selected to perform the optimum discrimination at that time.
The present invention compensates for the disadvantages of the two techniques (FEC and DFE) described in the prior art.
[0006]
The problem with FEC is that the bit rate increases. For example, a so-called superFEC (here, an example of a concatenated FEC code) which is currently being studied in a submarine system is a 7% code and a 12.5% code connected in a column, and a total of 22% redundant codes (See Non-Patent Document 2). At this time, the coding gain achieves 7.7 dB (5.8 dB when 7% code is used alone). However, for ultra-high-speed transmission such as 40 Gbit / s, the bit rate becomes 49 Gbit / s, and there is a possibility that the speed margin of the electronic circuit will be squeezed. Here, the necessity of a circuit called an interleaver for mixing the bit transmission order between the two encoding circuits also complicates the circuit scale. Further, since a technique called iterative decoding is used, decoding delay cannot be ignored. Therefore, although it is a classical problem, there is a demand for a method of increasing the coding gain by reducing the increase in the bit rate. Another problem is that FEC is not very effective for errors in the burst. For a slow change, such as polarization mode dispersion, it is assumed that most bits in the codeword are erroneous. In such a case, FEC is not always effective (see Non-Patent Document 3).
[0007]
The problem of the DFE is that it requires a processing time due to the provision of the feedback control circuit, and cannot follow a rapid change. In order to feed back the output result of the variable identification circuit (or the output results of the selection switches of a plurality of identification circuits), calculate the algorithm based on the feedback, and set the optimal identification value, the first few to several hundred bits are set. Misidentified. Therefore, DFE is effective for fading, but is not effective for uncorrelated errors such as noise.
[0008]
[Non-patent document 1]
F. Buchali et al. , "Adaptive decision feedback equalizer for 1 OGbit / s dispersion migration", ECOC'OO, 5.2.5.
[Non-patent document 2]
O. A. Sab, FEC technologies in submarine transmission systems ", OFC'01, TuF-1
[Non-Patent Document 3]
M. Tomizawa et al. , "FEC performance in PMD-limited high-speed optical transmission systems", ECOC'OO, 5.2.4.
[0009]
[Problems to be solved by the invention]
The present invention has been made in view of the above circumstances, and its object is to apply both to a system limited to noise and to a system limited to fading, and to limit and increase the transmission bit rate. It is an object of the present invention to provide a receiving circuit capable of improving bit errors without any error and a digital transmission system using the same.
[0010]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem, and the invention according to claim 1 distributes a received signal to n (n is a positive integer) lines and further converts each signal of the n lines into k signals. (K is a positive integer) and a first discriminating circuit set including n discriminating circuits having the same first threshold value and receiving the signal of the nth line, and a distributing means for distributing the signals to the lines. A second identification circuit set including n identification circuits having a threshold value of 2 and receiving the signal of the n line;... A k-th discriminating circuit set including n discriminating circuits for receiving the signals of the above, an adding circuit for performing an analog sum of the signals of the n lines, and an output of the adding circuit as inputs, the first to k-th K classifiers having threshold values of: and the identification results of the first to k-th identification circuit groups are input, and A control circuit for detecting the number of identification circuits having the same identification result every time, selecting a set having the largest number, and outputting the selection result; and the k classifiers based on the output of the control circuit. And a selection circuit for selecting and outputting one of the outputs.
[0011]
According to a second aspect of the present invention, a conversion unit for converting a received optical signal into an electric signal, and the electric signal output from the conversion unit are distributed to n (n is a positive integer) lines, and each of the n lines is A first identification circuit set including distribution means for further distributing the signal to k (k is a positive integer) lines and n identification circuits having the same first threshold value and receiving the n-line signal; , A second identification circuit set including n identification circuits having the same second threshold value and receiving the signal of the n line, and having the same k-th threshold value. A k-th identification circuit set including n identification circuits that receive the n-line signals, an addition circuit that performs an analog sum of the n-line signals, and an output of the addition circuit, K classifiers having first to k-th thresholds and identification of the first to k-th identification circuit sets And a control circuit that detects the number of identification circuits having the same identification result for each set, selects the set having the largest number, and outputs the selection result, based on the output of the control circuit. A selection circuit for selecting and outputting one of the outputs of the k classifiers.
[0012]
According to a third aspect of the present invention, there is provided an optical distributor for distributing a received optical signal to n (n is a positive integer) lines, n light receiving circuits for converting each optical signal of the n lines into an electric signal, N distribution circuits for distributing the outputs of the n light receiving circuits to k (k is a positive integer) lines, respectively, have the same first threshold value, and each output of the n distribution circuits is A first discriminating circuit set including n discriminating circuits to be received, and a second discriminating circuit including n discriminating circuits having the same second threshold value and receiving respective outputs of the n distributing circuits. ..., The k-th discriminating circuit set including the same k-th threshold value and receiving the outputs of the n distributing circuits, and the k-th discriminating circuit set; And an adder circuit for performing an analog sum of the outputs of the first and second outputs. , And the identification results of the first to k-th identification circuit groups are input, the number of identification circuits having the same identification result for each group is detected, and the group having the largest number is selected. A receiving circuit comprising: a control circuit that outputs the selection result; and a selection circuit that selects and outputs one of the outputs of the k classifiers based on the output of the control circuit. .
[0013]
According to a fourth aspect of the present invention, in the receiving circuit according to the third aspect, instead of the optical distributor, an optical signal that converts an optical frequency of the received optical signal and outputs optical signals of a plurality of optical frequencies. A frequency conversion circuit, and an optical demultiplexer that splits optical signals of a plurality of optical frequencies output from the optical frequency conversion circuit for each optical frequency and inputs the optical signals to the light receiving circuits. I do.
[0014]
According to a fifth aspect of the present invention, there is provided a distribution means for distributing a reception signal to n (n is a positive integer) lines, n identification circuits having the same threshold value and receiving the signals of the n lines, An adder circuit for performing an analog sum of the signals of the n lines; an input circuit which receives an output of the adder circuit, and has a threshold value equal to a threshold value of the identification circuit; A control circuit for inputting a result and detecting whether or not the identification results of the n identification circuits match; and selecting an output signal of the fixed voltage generator when the control circuit does not output a match. And a selection circuit for selecting and outputting the output of the addition circuit when the signal is output.
[0015]
According to a sixth aspect of the present invention, there is provided an optical distributor for distributing a received optical signal to n (n is a positive integer) lines, n light receiving circuits for converting each optical signal of the n lines into an electric signal, N identification circuits having the same threshold value and receiving respective outputs of the n light receiving circuits, an adding circuit for performing an analog sum of the outputs of the n light receiving circuits, An output, and a discriminator having a threshold value equal to the threshold value of the discrimination circuit; and a discrimination result of the discrimination circuit, and discriminating whether the discrimination results of the n discrimination circuits match. And a selection circuit that selects the output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs the output of the addition circuit when the match is output. A receiving circuit, comprising:
[0016]
8. A transmitting apparatus for transmitting a digital data signal, and a receiving apparatus for receiving the digital data signal transmitted via a transmission line, comparing the digital data signal with a predetermined threshold value, and performing identification and reproduction. Wherein the receiving device distributes the digital data signal to n (n is a positive integer) lines and further converts each signal of the n lines to k (k is a positive integer) line. Distributing means for distributing, a first identification circuit set having n same identification threshold circuits having the same first threshold value and receiving the signal of the n lines, and having the same second threshold value; A second discrimination circuit set including n discrimination circuits for receiving the n-line signals, and n discrimination circuits having the same k-th threshold value and receiving the n-line signals A k-th identification circuit set consisting of An adder circuit for performing an analog sum of the signals; k input classifiers which receive the output of the adder circuit and have the first to kth threshold values; and the first to kth identification circuit sets And a control circuit for detecting the number of identification circuits having the same identification result for each set, selecting the set having the largest number, and outputting the selection result, and an output of the control circuit. And a selection circuit for selecting and outputting one of the outputs of the k discriminators on the basis of (i).
[0017]
The invention according to claim 8 is a transmission device for transmitting a digital data optical signal, an electric signal obtained based on the received optical signal, receiving the digital data optical signal transmitted via an optical transmission line. And a receiving device for performing discrimination and reproduction by comparing with a predetermined threshold value, wherein the receiving device comprises: a converting means for converting the digital data optical signal into an electric signal; and an output from the converting means. Distribution means for distributing the obtained electric signals to n (n is a positive integer) lines, and further distributing each signal of the n lines to k (k is a positive integer) lines, And a first identification circuit set including n identification circuits receiving the signal of the n line, and n identification circuits having the same second threshold value and receiving the signal of the n line. A second identification circuit set; .., A k-th identification circuit set including the n-th identification circuit having the same k-th threshold value and receiving the n-line signal, and an addition for performing an analog sum of the respective signals on the n-th line A circuit, an output of the adder circuit, and k discriminators having the first to k-th threshold values, and the identification results of the first to k-th identification circuit groups are input. A control circuit for detecting the number of identification circuits having the same identification result every time, selecting a set having the largest number, and outputting the selection result; and the k classifiers based on the output of the control circuit. And a selection circuit for selecting and outputting one of the outputs.
[0018]
A transmitting device for transmitting a digital data optical signal, an electric signal obtained based on the received optical signal, receiving the digital data optical signal transmitted via an optical transmission line, And a receiving device for performing discrimination and reproduction by comparing with a predetermined threshold value, wherein the receiving device distributes the digital data optical signal to n (n is a positive integer) lines. Device, n light receiving circuits for converting each optical signal of the n lines into an electric signal, and n distribution circuits for distributing the outputs of the n light receiving circuits to k (k is a positive integer) lines, respectively. And a first identification circuit set including n identification circuits having the same first threshold value and receiving respective outputs of the n distribution circuits, and having the same second threshold value, N pieces of knowledge that receive each output of the n pieces of distribution circuits A second identification circuit set consisting of circuits;... A k-th identification circuit set consisting of n identification circuits having the same k-th threshold value and receiving respective outputs of the n distribution circuits An addition circuit that performs an analog sum of the outputs of the n distribution circuits; an input of the output of the addition circuit; and k discriminators having the first to k-th threshold values; The identification results of the first to k-th identification circuit groups are input, the number of identification circuits having the same identification result for each group is detected, the group with the largest number is selected, and the selection result is output. A digital transmission system comprising: a control circuit; and a selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit.
[0019]
According to a tenth aspect of the present invention, in the digital transmission system according to the ninth aspect, an optical signal of a plurality of optical frequencies is output by converting an optical frequency of the digital data optical signal instead of the optical distributor. And an optical splitter for splitting optical signals of a plurality of optical frequencies for each optical frequency and inputting them to the respective light receiving circuits.
According to an eleventh aspect of the present invention, in the digital transmission system according to the ninth aspect, the transmitting device modulates a plurality of frequency mode optical pulses with a digital data signal and transmits the modulated optical pulses. Instead of the distributor, an optical demultiplexer for separating optical pulse signals in a plurality of optical frequency modes and inputting them to the respective light receiving circuits is provided.
[0020]
According to a twelfth aspect of the present invention, in the digital transmission system according to the ninth aspect, the transmitting device modulates a continuous light of a plurality of optical frequencies with a digital data signal and transmits the modulated light, and the receiving device transmits the optical light. Instead of the distributor, an optical demultiplexer for separating an optical modulation signal into a plurality of optical frequencies and inputting the optical modulation signal to each of the light receiving circuits is provided.
According to a thirteenth aspect of the present invention, in the digital transmission system according to the ninth aspect, the transmitting device modulates a plurality of polarization mode lights by a digital data signal and transmits the modulated light, and the receiving device transmits the light in the polarization mode. Instead of the splitter, a plurality of optical polarization splitters for separating the optical modulation signal in the ready mode and inputting the split optical modulation signal to each of the light receiving circuits is provided.
[0021]
According to a fourteenth aspect of the present invention, in the digital transmission system according to the ninth aspect, the transmitting device modulates a continuous light or an optical pulse with a digital data signal and transmits the modulated signal, and the receiving device includes the optical distributor. Instead of the above, an optical sideband separator is provided which divides the optical spectrum of the received optical modulation signal and inputs the divided optical spectrum to each of the light receiving circuits.
[0022]
According to a fifteenth aspect of the present invention, in the digital transmission system according to any one of the seventh to ninth aspects, the transmitting device transmits the digital data signal or the digital data optical signal via a plurality of transmission paths. The receiving device includes a delay circuit for adjusting a delay time difference between signals transmitted through the plurality of transmission paths, and a signal from each transmission path receives the identification circuit and the addition circuit via the delay circuit. It is characterized by being input to.
[0023]
17. A transmitting apparatus for transmitting a digital data signal, and a receiving apparatus for receiving the digital data signal transmitted via a transmission path, comparing the digital data signal with a predetermined threshold value, and performing identification and reproduction. And a distributing means for distributing the received signal to n (n is a positive integer) lines, and n receiving units for receiving the signals of the n lines. An identification circuit, an addition circuit that performs an analog sum of the signals of the n lines, an input circuit that receives an output of the addition circuit, and has a threshold value that is the same as the threshold value of the identification circuit; A control circuit for receiving the identification result of the identification circuit and detecting whether or not the identification results of the n identification circuits match; and an output signal of a fixed voltage generator when the control circuit does not output a match. Select and match When output is a digital transmission system characterized by comprising a selection circuit for selectively outputting the output of said adder circuit.
[0024]
18. A transmitting apparatus for transmitting a digital data signal, and a receiving apparatus for receiving the digital data signal transmitted through a transmission line, comparing the digital data signal with a predetermined threshold value, and performing identification and reproduction. Wherein the receiving device converts the optical signal of the n lines into an electric signal, and an optical distributor for distributing the digital data optical signal to n (n is a positive integer) lines. n light receiving circuits, n identification circuits having the same threshold value and receiving the signals of the n lines, an adding circuit for performing an analog sum of the signals of the n lines, and an output of the adding circuit , And a discriminator having a threshold value equal to the threshold value of the discriminating circuit, and a discriminating result of the discriminating circuit, and determining whether the discriminating results of the n discriminating circuits match. Control times to detect And a selection circuit that selects an output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs an output of the addition circuit when a match is output. Digital transmission system.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a receiving circuit according to one embodiment of the present invention. In this figure, 1 is an optical amplifier to which an optical reception signal is input, 2 is an optical distributor for distributing output light of the optical amplifier 1, 3-1 to 3-n are optical amplifiers, and 4-1 to 4-n are This is a light receiving circuit that converts each output light of the optical amplifiers 3-1 to 3-n into an electric signal. Reference numeral 5-1 denotes a distribution circuit which supplies the output of the light receiving circuit 4-1 to the identification circuits 61-1 to 6k-1 and the analog addition circuits 7-1 to 7-k. Similarly, a distribution circuit 5-n supplies the output of the light receiving circuit 4-n to the identification circuits 61-n to 6kn and the analog addition circuits 7-1 to 7-k.
[0026]
The identification circuits 61-1 to 61-n identify the input signal based on the threshold value 1 and output an identification result (“1” or “0”) to the control circuit 9. Similarly, the identification circuits 6k-1 to 6k-n identify the input signal based on the threshold value k, and output an identification result ("1" or "0") to the control circuit 9. The control circuit 9 inputs the respective identification results of the identification circuits 61-1 to 6k-n, and identifies the identification circuits 61-1 to 61-n, 62-1 to 62-n, ..., 6k-1 to 6k-n. The number of discriminating circuits for which the discrimination results are the same for each set is determined. Then, the set having the largest number is selected (majority decision logic), and the threshold value of the set is output to the selection circuit 10. For example, all the outputs of the identification circuits 61-1 to 61-n are "1", and the output of each set of the identification circuits 62-1 to 62-n,. When both “1” and “0” are included, the control circuit 9 outputs the threshold value 1 to the selection circuit 10.
[0027]
The analog addition circuits 7-1 to 7-k add the outputs of the distribution circuits 5-1 to 5-n, respectively, and output the addition results to the identification circuits 8-1 to 8-k. The discriminating circuits 8-1 to 8-k discriminate the outputs of the analog adding circuits 7-1 to 7-k based on the thresholds 1 to k, respectively, and discriminate the result ("1" or "0"). To the selection circuit 10. The selection circuit 10 selects and outputs the output of the discrimination circuit (any one of 8-1 to 8-k) having a threshold value equal to the threshold value output from the control circuit 9.
[0028]
According to the above-described receiving circuit, a good quality threshold value is selected for bit-by-bit, and the error rate characteristic is improved. In this receiving circuit, the outputs of the plurality of control system identification circuits 61-1 to 6k-n are directly connected to the control circuit 9, and only the outputs of the identification circuits 61-1 to 6k-n are monitored to perform the control. The circuit 9 controls the selection circuit 10. Therefore, it is characterized in that feedback control such as DFE is not required.
[0029]
In this receiving circuit, n light receiving circuits 4-1 to 4-n are provided. In this case, thermal noise and shot noise of the light receiving circuits 4-1 to 4-n can be treated as independent events. In this case, the S / N ratio of the light incident on the light receiving circuits 4-1 to 4-n is reduced by the number of branches of the light receiving circuits 4-1 to 4-n. The output after the preamplifier is split by an optical coupler. Further, the optical output after the preamplifier is branched and then amplified by n optical postamplifiers.
[0030]
Since the bit error rate characteristic of an optical signal is substantially determined by the S / N just before the light enters the optical amplifier 1, even if there is a loss corresponding to the number of branches after being amplified, it hardly contributes to the bit error rate characteristic. Known [Ishio et al., Optical Amplifiers and Their Applications (Ohm)]. In the case of the configuration of FIG. 1, the noise of the optical amplifier can be treated as an independent event, and further effects can be expected. This is because it is known that noise in an optical amplifier and a light receiving circuit is dominant in an actual optical transmission system.
[0031]
The circuits after the distribution circuits 5-1 to 5-n include a control system circuit including the identification circuits 61-1 to 6kn and the control circuit 9, an analog addition circuit 7-1 to 7-k, and an identification circuit 8-1. -8-k and a main signal system circuit including a selection circuit 10.
Regarding the control system circuit, the optical signal after optical transmission is subjected to waveform deterioration such as S / N deterioration and fading, and noises in the light receiving circuits 4-1 to 4-n and the identification circuits 61-1 to 6k-n. Is added, the signal to which noise is added is identified, and the signal is output. The important point is that by providing a plurality of identification circuits 61-1 to 6k-n, independent noise is added to each circuit. Therefore, even if a signal of "1" is erroneously recognized as "0" at a certain moment of a certain identification circuit having a certain threshold value, "1" is correctly recognized by a different identification circuit at the same threshold value and the same moment. Could have been.
[0032]
Here, the control circuit 9 monitors the outputs of the identification circuits 61-1 to 6kn. If all the results are the same among the n identification circuits for each threshold value, there is a high probability that the identification is correct. On the other hand, if some of the outputs of the n identification circuits have different results, there is a high probability that one of them is incorrect. The control circuit 9 adopts the threshold value in which the n identification results are the same or the result of the threshold value in which the same identification result is the largest, and determines the identification result of the same threshold value in the main signal system circuit. select. That is, the logic of the control circuit 9 can be said to be majority logic. This improves the bit error characteristics.
[0033]
On the other hand, in the main signal system circuit, the outputs from the separate light receiving circuits 4-1 to 4-n are subjected to analog addition. This utilizes the fact that, when the same main signal accompanied by different noises is added to the analog, the signal component becomes n times and the noise component becomes Δn times, thereby improving the S / N ratio. A threshold value is selected for each bit by the logic from the control circuit 9 for the signal having an improved S / N, thereby lowering the error rate. FIG. 2 shows a configuration example of a special case where n = k = 2, and portions corresponding to the respective portions in FIG. 1 are denoted by the same reference numerals. Here, the simplest exclusive OR circuits 9a and 9b are used for majority logic. The exclusive OR itself can operate at about 40 Gbit / s, and can be realized in an ultra-high-speed system.
[0034]
FIG. 3 schematically shows the transition of the signal waveform. The optical input waveform is a waveform with noise. By analogly adding signals with independent noises to this waveform, the intensity of the signal component is doubled and the noise component is increased by a factor of two, so that the signal has an S / N ratio improved by 1.5 dB. Then, a threshold value is selected, and if "1", a low threshold value is selected, and if "0", a high threshold value is selected, and the signal error rate is suppressed.
[0035]
Next, a second embodiment of the present invention will be described. FIG. 4 is a block diagram showing the configuration of the receiving circuit according to the embodiment. In this embodiment, an optical frequency conversion circuit 13 is provided downstream of the optical amplifier 12. Here, a wavelength conversion device using a non-linear effect may be used for the optical frequency conversion circuit 13. One optical signal is converted into optical signals of a plurality of frequencies that are also encoded. The plurality of optical frequencies are collectively amplified by the second optical amplifier 14 and then separated by the optical frequency separation filter 15. Then, the separated optical signal is input to the reception basic circuit A (see FIG. 2). In the above configuration, although the number of the second optical amplifier 14 is one, the noise received by the optical signals of different frequencies can be treated as two series of independent events, and the error correction effect can be reduced while limiting the number of optical amplifiers. Can be demonstrated.
[0036]
Next, a digital optical transmission system according to a third embodiment of the present invention will be described. In this embodiment, as shown in FIG. 5, the transmitting device has a signal distribution function. Since a plurality of independent signals propagate through a plurality of transmission paths, noise of the optical repeater in the middle of the transmission path can be an independent event. That is, a bit error due to noise from the optical repeater can be corrected. Here, the transmitting device distributes the signal to a plurality (here, two, but not necessarily). The signal arrives at the receiving circuit through a plurality of transmission paths. Here, since the transmission path lengths are usually different, buffer memories 17-1 and 17-2 for adjusting the delay time are provided. Note that reference numeral B is the processing circuit shown in FIG.
[0037]
Next, a fourth embodiment of the present invention will be described. The fourth embodiment can correct a bit error due to noise from an optical repeater without using a plurality of transmission paths. FIG. 6 shows the configuration of this embodiment. Here, the transmission device includes a pulse light generator having a plurality of frequencies. Here, two frequencies are shown, but not necessarily two. This optical pulse may be a carrier-suppressed RZ pulse whose optical phase is inverted from each other (Japanese Patent Application No. 2000-82997).
[0038]
Further, the transmitting device includes means for modulating the optical pulse with digital data. The means for modulating here may be a normal NRZ (in this case, a Carrier Suppressed Rerun-to-Zero: CS-RZ code) or a duobinary modulation (in this case, a Duobinary Carrier Suppressed Return-to-Zero). Zero: DCS-RZ [Y. Miyamoto et al., OFC'Ol, TuU4] Alternatively, a method of transmitting a normal NRZ signal and extracting two sidebands on the receiving side may be used. The waves may be transmitted orthogonally and split on the receiving side into two polarizations.
[0039]
The receiving circuit is characterized by having a first optical amplifier 21 and an optical frequency separation circuit 22 (Single Side Band (SSB) separation) after that (in the case of polarization separation, PBS: Polarization Mode Splitter). Become). Then, the output light of the optical frequency separation circuit 22 is amplified by the optical amplifiers 23-1 and 23-2 and input to the basic receiving circuit A (see FIG. 2).
[0040]
Hereinafter, a method of frequency-separating CR-RZ will be described. Separating the two modes of the RZ pulse (CS-RZ or DCS-RZ) by respective filters, the two receivers receive these signals. Advantages of this embodiment include the following. Light in the two frequency modes is independent, and noise received from all optical repeaters during transmission is random noise that has no correlation between the modes. Therefore, the present embodiment has an effect of correcting a bit error due to noise from the optical repeater. In long-distance long-span systems with many optical repeaters, it is known that noise from optical repeaters is dominant among error sources [(Ishio et al., Optical Amplifiers and Their Applications (Ohm Co., Ltd.) Therefore, the present embodiment is also effective for a multi-relay long distance system.
[0041]
The transmitting device modulates the continuous light or the optical pulse with a digital data signal and transmits the modulated signal. The receiving device replaces the optical frequency separating circuit 22 and divides the optical spectrum of the received modulated optical signal to each light receiving circuit. May be provided with an optical side-band separator for inputting the signal to the input side.
[0042]
Next, a fifth embodiment of the present invention will be described with reference to FIG. In this embodiment, two identification circuits 61-1 and 61-2 are provided in which the same threshold is set and the threshold is set higher (lower) than the standard. And an identification circuit 8-1 in which the same threshold value as that of the identification circuit 8 is set. Further, a fixed voltage generator 32 for inputting a signal of logic "1" (or "0") to the selection circuit is provided. An exclusive OR circuit 31 is provided as a control circuit. If the exclusive OR circuit 31 does not match the identification results of the two identification circuits 61-1 and 61-2, a fixed voltage generation circuit 31 is provided. The selection circuit 10 is controlled so as to select the output signal of the detector 32, and if the identification results of the two identification circuits 61-1 and 61-2 match, the identification result output of the identification circuit 8-1 is selected. The selection circuit 10 is controlled so as to perform the operation.
[0043]
【The invention's effect】
According to the present invention, it is possible to improve bit errors without increasing the transmission bit rate. In addition, since a threshold value with good quality (high probability) is selected, it is effective for deterioration such as facing (it continues to select an optimum threshold value for a while). Furthermore, since there is no feedback connection and an instantaneous threshold value is selected for each hit, errors at the beginning of the control feedback operation are avoided, and there is also an effect on random errors such as uncorrelated noise for each bit. The present invention is useful not only for a repeaterless long-haul system but also for a long haul linear optical repeater system.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a receiving circuit according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration example of the receiving circuit when n = k = 2.
FIG. 3 is a waveform chart for explaining the operation of the receiving circuit.
FIG. 4 is a block diagram showing a configuration of a second embodiment of the present invention.
FIG. 5 is a block diagram showing a configuration of a third embodiment of the present invention.
FIG. 6 is a block diagram showing a configuration of a fourth embodiment of the present invention.
FIG. 7 is a block diagram showing a configuration of a fifth embodiment of the present invention.
[Explanation of symbols]
1: Optical amplifier
2 ... Optical distributor
3-1-3-n: Optical amplifier
4-1 to 4-n ... light receiving circuit
5-1 to 5-n ... distribution circuit
61-1 to 6kn-identification circuit
7-1 to 7-k ... analog addition circuit
8-1 to 8 -k ... identification circuit
9 ... Control circuit
9a, 9b, 31 ... exclusive OR circuit
10 ... Selection circuit
12, 21, 23-1, 23-2 ... optical amplifier
13. Optical frequency conversion circuit
14. Optical amplifier
15, 22 ... Optical frequency separation circuit
32 ... fixed voltage generator

Claims (17)

Distribution means for distributing the received signal to n (n is a positive integer) lines and further distributing each signal of the n lines to k (k is a positive integer) line;
A first identification circuit set including n identification circuits having the same first threshold value and receiving the n-line signals; and a first identification circuit set having the same second threshold value and having the same n-th line signal. A second discriminating circuit set consisting of n discriminating circuits to be received,..., A k-th discriminating circuit consisting of n discriminating circuits having the same k-th threshold value and receiving the signal of the n-th line Circuit set,
An addition circuit that performs an analog sum of the signals of the n lines;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A receiving circuit comprising: Conversion means for converting the received optical signal into an electric signal;
Distribution means for distributing the electric signal output from the conversion means to n (n is a positive integer) lines and further distributing each signal of the n lines to k (k is a positive integer) lines;
A first identification circuit set including n identification circuits having the same first threshold value and receiving the n-line signals; and a first identification circuit set having the same second threshold value and having the same n-th line signal. A second discriminating circuit set consisting of n discriminating circuits to be received,..., A k-th discriminating circuit consisting of n discriminating circuits having the same k-th threshold value and receiving the signal of the n-th line Circuit set,
An addition circuit that performs an analog sum of the signals of the n lines;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A receiving circuit comprising: An optical distributor for distributing a received optical signal to n (n is a positive integer) lines;
N light receiving circuits for converting each optical signal of the n lines into an electric signal;
N distribution circuits for distributing the outputs of the n light receiving circuits to k (k is a positive integer) lines, respectively;
A first discriminating circuit set having the same first threshold value and including n discriminating circuits receiving respective outputs of the n distributing circuits, and the same second threshold value having the same second threshold value; A second discriminating circuit set including n discriminating circuits receiving the respective outputs of the plurality of distributing circuits,... Having the same k-th threshold value and receiving the respective outputs of the n distributing circuits a k-th identification circuit set including n identification circuits;
An adder circuit for performing an analog sum of each output of the n distribution circuits;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A receiving circuit comprising: Instead of the optical distributor, an optical frequency conversion circuit that converts an optical frequency of the received optical signal and outputs optical signals of a plurality of optical frequencies, and a plurality of optical frequencies output from the optical frequency conversion circuit. 4. The receiving circuit according to claim 3, further comprising an optical demultiplexer for demultiplexing an optical signal for each optical frequency and inputting the demultiplexed optical signal to each of the light receiving circuits. Distribution means for distributing the received signal to n (n is a positive integer) lines;
N identification circuits having the same threshold value and receiving the signals of the n lines;
An addition circuit that performs an analog sum of the signals of the n lines;
A classifier having an output of the adder circuit as an input and having a threshold value equal to the threshold value of the identification circuit;
A control circuit that receives an identification result of the identification circuit and detects whether the identification results of the n identification circuits match each other;
A selection circuit that selects the output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs the output of the addition circuit when a match is output;
A receiving circuit comprising: An optical distributor for distributing a received optical signal to n (n is a positive integer) lines;
N light receiving circuits for converting each optical signal of the n lines into an electric signal;
N identification circuits having the same threshold value and receiving respective outputs of the n light receiving circuits;
An addition circuit that performs an analog sum of the outputs of the n light receiving circuits;
A classifier having an output of the adder circuit as an input and having a threshold value equal to the threshold value of the identification circuit;
A control circuit that receives an identification result of the identification circuit and detects whether the identification results of the n identification circuits match each other;
A selection circuit that selects the output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs the output of the addition circuit when a match is output;
A receiving circuit comprising: A digital transmission system comprising: a transmission device that transmits a digital data signal; and a reception device that receives the digital data signal transmitted via a transmission path and performs identification reproduction by comparing the digital data signal with a predetermined threshold value.
The receiving device,
Distribution means for distributing the digital data signal to n (n is a positive integer) lines and further distributing each signal of the n lines to k (k is a positive integer) line;
A first identification circuit set including n identification circuits having the same first threshold value and receiving the n-line signals; and a first identification circuit set having the same second threshold value and having the same n-th line signal. A second discriminating circuit set consisting of n discriminating circuits to be received,..., A k-th discriminating circuit consisting of n discriminating circuits having the same k-th threshold value and receiving the signal of the n-th line Circuit set,
An addition circuit that performs an analog sum of the signals of the n lines;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A digital transmission system comprising: A transmitting device for transmitting a digital data optical signal, receiving the digital data optical signal transmitted through the optical transmission line, and comparing an electric signal obtained based on the received optical signal with a predetermined threshold value; And a receiving device for performing identification and reproduction by
The receiving device,
Conversion means for converting the digital data optical signal into an electric signal,
Distribution means for distributing the electric signal output from the conversion means to n (n is a positive integer) lines and further distributing each signal of the n lines to k (k is a positive integer) lines;
A first identification circuit set including n identification circuits having the same first threshold value and receiving the n-line signals; and a first identification circuit set having the same second threshold value and having the same n-th line signal. A second discriminating circuit set consisting of n discriminating circuits to be received,..., A k-th discriminating circuit consisting of n discriminating circuits having the same k-th threshold value and receiving the signal of the n-th line Circuit set,
An addition circuit that performs an analog sum of the signals of the n lines;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A digital transmission system comprising: A transmitting device for transmitting a digital data optical signal, receiving the digital data optical signal transmitted through the optical transmission line, and comparing an electric signal obtained based on the received optical signal with a predetermined threshold value; And a receiving device for performing identification and reproduction by
The receiving device,
An optical distributor for distributing the digital data optical signal to n (n is a positive integer) lines;
N light receiving circuits for converting each optical signal of the n lines into an electric signal;
N distribution circuits for distributing the outputs of the n light receiving circuits to k (k is a positive integer) lines, respectively;
A first discriminating circuit set having the same first threshold value and including n discriminating circuits receiving respective outputs of the n distributing circuits, and the same second threshold value having the same second threshold value; A second discriminating circuit set including n discriminating circuits receiving the respective outputs of the plurality of distributing circuits,... Having the same k-th threshold value and receiving the respective outputs of the n distributing circuits a k-th identification circuit set including n identification circuits;
An adder circuit for performing an analog sum of each output of the n distribution circuits;
K discriminators having an input of the output of the adder circuit and having the first to k-th threshold values,
The identification results of the first to k-th identification circuit sets are input, the number of identification circuits having the same identification result for each group is detected, the group having the largest number is selected, and the selection result is output. Control circuit,
A selection circuit that selects and outputs one of the outputs of the k classifiers based on an output of the control circuit;
A digital transmission system comprising: Instead of the optical distributor, an optical frequency conversion circuit that converts an optical frequency of the digital data optical signal and outputs an optical signal of a plurality of optical frequencies, and an optical signal of a plurality of optical frequencies for each optical frequency The digital transmission system according to claim 9, further comprising an optical demultiplexer for demultiplexing and inputting to each of the light receiving circuits. The transmitting device modulates and transmits a plurality of frequency mode optical pulses with a digital data signal, and the receiving device replaces the optical distributor and separates a plurality of optical frequency mode optical pulse signals. 10. The digital transmission system according to claim 9, further comprising an optical demultiplexer for inputting to each light receiving circuit. The transmitting device modulates and transmits continuous light of a plurality of optical frequencies with a digital data signal, and the receiving device separates the optical modulation signal into a plurality of optical frequencies, instead of the optical distributor, and transmits each of the plurality of optical modulated signals. The digital transmission system according to claim 9, further comprising an optical demultiplexer for inputting to the light receiving circuit. The transmitting device modulates a plurality of polarization mode lights with a digital data signal and transmits the modulated light, and the receiving device replaces the optical distributor and separates the optical modulation signals into a plurality of prepended modes, and The digital transmission system according to claim 9, further comprising an optical polarization splitter for inputting to each light receiving circuit. The transmitting device modulates a continuous light or an optical pulse with a digital data signal and transmits the modulated light, and the receiving device replaces the optical distributor and divides an optical spectrum of an optical modulation signal to be received to generate each of the light receiving circuits. The digital transmission system according to claim 9, further comprising an optical sideband separator for inputting the signal to the input side. The transmitting device transmits a digital data signal or a digital data optical signal through a plurality of transmission paths,
The receiving device includes a delay circuit for adjusting a delay time difference between signals transmitted through the plurality of transmission paths, and a signal from each transmission path is input to the identification circuit and the addition circuit via the delay circuit. The digital transmission system according to any one of claims 7 to 9, wherein: A digital transmission system comprising: a transmission device that transmits a digital data signal; and a reception device that receives the digital data signal transmitted via a transmission path and performs identification reproduction by comparing the digital data signal with a predetermined threshold value.
The receiving device,
Distribution means for distributing the received signal to n (n is a positive integer) lines;
N identification circuits having the same threshold value and receiving the signals of the n lines;
An addition circuit that performs an analog sum of the signals of the n lines;
A classifier having an output of the adder circuit as an input and having a threshold value equal to the threshold value of the identification circuit;
A control circuit that receives an identification result of the identification circuit and detects whether the identification results of the n identification circuits match each other;
A selection circuit that selects the output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs the output of the addition circuit when a match is output;
A digital transmission system comprising: A digital transmission system comprising: a transmission device that transmits a digital data signal; and a reception device that receives the digital data signal transmitted via a transmission path and performs identification reproduction by comparing the digital data signal with a predetermined threshold value.
The receiving device,
An optical distributor for distributing the digital data optical signal to n (n is a positive integer) lines;
N light receiving circuits for converting each optical signal of the n lines into an electric signal;
N identification circuits having the same threshold value and receiving the signals of the n lines;
An addition circuit that performs an analog sum of the signals of the n lines;
A classifier having an output of the adder circuit as an input and having a threshold value equal to the threshold value of the identification circuit;
A control circuit that receives an identification result of the identification circuit and detects whether the identification results of the n identification circuits match each other;
A selection circuit that selects the output signal of the fixed voltage generator when the control circuit does not output a match, and selects and outputs the output of the addition circuit when a match is output;
A digital transmission system comprising:

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