JP2007081782A - Optical transmission apparatus, optical transmission system, and alarm issue method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical transmission apparatus for issuing an alarm when transmission quality is deteriorated and no margin for error correction capability exists, and to provide an optical transmission system and an alarm issue method. <P>SOLUTION: The optical transmission apparatus includes a plurality of transponders (36) and an alarm control section (37). Each of the transponders (36) discriminates issue of a quality deterioration alarm representing the deterioration in the transmission quality on the basis of data received from a transmission line. The alarm control section (37) collects issued quality deterioration alarms and controls issuing of a transmission line quality alarm representing the quality deterioration in the transmission lines on the basis of the number of the transponders (36) for issuing the quality deterioration alarms among whole the transponders (36). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical transmission device, an optical transmission system, and a method for issuing an alarm indicating deterioration of a transmission signal.

  Optical transmission technologies such as wavelength division multiplexing (WDM) are attracting attention as technologies for coping with the explosive expansion of IP traffic in recent years. As a next generation optical transmission network based on WDM, OTN (Optical Transport Network) is being standardized in ITU-T (International Telecommunication Union-Telecommunication Standardizer Sector). As shown in FIG. 1, the OTN is located between a digital client layer and an optical medium which is a physical layer, and an optical channel layer (OCh layer), an optical multiplexing section layer (OMS layer), an optical transmission section layer ( 3 layers of OTS layer). The OCh layer provides end-to-end networking of optical channels that transparently transmit higher layer information (digital). The OMS layer provides a function of transmitting wavelength multiplexed optical signals (corresponding to a plurality of optical channels) through the wavelength multiplexing section. The OTS layer is located between the OMS layer and the optical medium, and provides a function of transmitting wavelength-multiplexed optical signals via various optical media.

  In these optical transmissions, it is important to maintain the signal quality. For example, signal quality deterioration is prevented by FEC (Forward Error Correction) or the like. FEC is a forward error detection and correction method in which redundant data for error detection and correction is added before data is transmitted on the transmission side, and error detection and correction of received data are performed using the redundant data on the reception side. is there.

  In an optical transmission apparatus using FEC, a DEG (Signal Degrade) alarm is issued as an alarm indicating signal quality degradation in the FEC layer. Standardized in 798 Recommendation. For the determination of the DEG alarm, BIP-8 (Bit Interleaved Parity 8) after FEC correction is used. BIP is an error detection method that performs a parity check for each block.

At present, the FEC correction capability is improved, and for example, correction is possible to a substantially error-free level at a bit error rate of about 3 × 10 ⁻³ . Therefore, for example, even if the state of the transmission path gradually deteriorates, the error is corrected as long as it can be corrected by FEC. Therefore, since it seems that there is no problem in the quality of the signal, the DEG alarm is not issued. That is, when a DEG alarm is determined using BIP-8 after FEC correction, there is a possibility that the actual transmission quality has already deteriorated significantly. In other words, it cannot be determined from the DEG alarm using BIP-8 after FEC correction whether the state of the transmission line is a dangerous state near the limit of the FEC correction capability, or is a safe state with a sufficient margin. It will be.

The relationship between the FEC correction capability and the DEG alarm will be described in more detail with reference to FIG. FIG. 2 shows an example of the relationship, and shows two cases of high FEC correction capability and low correction capability. ITU-T G. The setting range of the DEG alarm issue threshold standardized by the 798 recommendation is a case where the BER (Bit Error Rate) after the FEC correction is in the range of 1 × 10 ⁻⁵ to 1 × 10 ⁻⁹ . As shown in FIG. 2, the range of the BER before FEC correction in which the BER after FEC correction is 1 × 10 ⁻⁵ to 1 × 10 ⁻⁹ is the range a in the case of FEC having a small correction capability. On the other hand, in the case of FEC having a high correction capability, it can be seen that the range of the BER before FEC correction is very narrow as the range b. For example, when the BER before FEC correction is 1 × 10 ^−3, a DEG alarm is issued in the case of FEC with a small correction capability. On the other hand, in the case of FEC having a large correction capability, the detected error is corrected, and therefore no DEG alarm is issued. In other words, in the case of FEC having a high correction capability, the BER for issuing a DEG alarm is not narrow until the transmission line quality is significantly deteriorated and the BER for issuing a DEG alarm is not severe.

  As shown below, techniques relating to error detection and correction of an optical transmission device, alarm output, and the like are known. Japanese Patent Application Laid-Open No. 2000-4260 discloses a technique relating to wavelength multiplexing and an optical signal monitoring method in an optical network. In this optical signal monitoring method, first, a received optical signal is converted into an electrical signal, and a transmission signal clock is extracted from the converted electrical signal. N (N ≧ 2) clocks each having a phase threshold arbitrarily shifted from the extracted transmission signal clock are generated. Based on the generated N clocks and the voltage amplitude threshold values respectively set corresponding to the N clocks, the bits of the electric signal are identified and N bit identification signals are output. The quality of the received optical signal is evaluated by performing a logical operation on the output N bit identification signals.

  Japanese Unexamined Patent Application Publication No. 2004-165833 discloses a technique related to an optical transmission apparatus. The optical transmission apparatus includes an error correction code adding unit, a drive circuit, an optical transmission path, a light receiving element, a detection unit, a calculation unit, and a control unit. The error correction code adding means adds an error correction code to the input signal. The drive circuit drives the light emitting element to emit an input signal as an optical signal. The optical transmission line transmits an optical signal. The light receiving element receives the optical signal transmitted through the optical transmission path. The detection unit detects the amount of received light signal received by the light receiving element. The calculation unit detects an error of the error correction code in the optical signal received by the light receiving element and calculates the error occurrence rate. The control unit performs light emission control of the drive circuit based on the amount of received light and the error occurrence rate.

  Japanese Patent Application Laid-Open No. 2003-224523 discloses a technique related to a dispersion equalization apparatus in an optical fiber transmission line. This distributed equalization apparatus includes error detection means, alarm detection means, variable dispersion equalization means, and control means. The error detection means detects transmission error information of an optical signal encoded with an error correction code and transmitted through an optical fiber transmission line. The alarm detection means detects alarm information related to transmission of the optical signal. The variable dispersion equalization means is provided before the error detection means and the alarm detection means, and adjusts a parameter that limits the transmission distance of the optical fiber transmission line based on the control signal. The control means generates a control signal using the transmission error information obtained by the error detection means and the alarm information obtained by the alarm detection means.

  Japanese Patent Laid-Open No. 2001-292066 discloses a technique related to an error correction device of a data transfer system. The error correction apparatus includes error correction calculation means for performing error correction processing on data to be corrected including an error correction code having a product code capable of correcting errors in the first direction and the second direction of the data block. The error correction calculation means includes first and second error correction means, and includes a first storage element and an error check means. The first error correction means corrects the first direction of the product code, and the second error correction means corrects the second direction. The first memory element can store data to be corrected. The error checking means performs an error check using an error check code in order to confirm that the correction by the error correction calculating means is not an error correction. This error check code is obtained by continuously providing error check codes to data in the first direction of a data block. Therefore, the error checking means includes first logic operation means, first direction error checking means, and second direction error checking means. The first logical operation means calculates the first error check result using the error amount detected by the error correction in the first direction and the data stored in the first storage element. The first direction error checking means performs error checking after error correction in the first direction according to the first error detection result. The second direction error checking means calculates a second error check result using the error amount detected at the time of error correction in the second direction, and performs a logical operation on the first and second error check results. Thus, an error check after error correction in the second direction is performed.

  Japanese Patent Laid-Open No. 2002-77111 discloses a technique related to a digital signal identification and reproduction method. In this identification / reproduction method, a digital signal is identified and reproduced from the input signal by determining whether or not the input signal exceeds a threshold value, and the digital signal after the identification / reproduction is error-corrected by a forward error correction method. At this time, the threshold value is corrected so that the number of error corrections indicating the number of error-corrected bits approaches zero.

  Japanese Patent Laid-Open No. 10-133899 discloses a technique relating to a method for predicting an uncorrectable error in an apparatus having an error correction function. In this error prediction method, first, the number of error corrections by the error correction function is counted. The number of error corrections and the set number of times set are compared. An uncorrectable error is predicted based on the comparison result.

JP 2000-4260 A JP 2004-165833 A JP 2003-224523 A JP 2001-292066 A JP 2002-77111 A JP-A-10-133899

In an optical transmission system and an optical transmission apparatus, it is considered that a sufficient margin for transmission quality is necessary in addition to error free of signals. However, conventionally, the DEG alarm is determined only from the comparison result of BIP-8 after FEC correction. For example, even if the transmission quality has deteriorated, if the bit error rate is about 3 × 10 ⁻³ , error correction is not possible due to FEC error correction, and an alarm cannot be issued in that state. In other words, even if the transmission quality margin has disappeared, it could not be warned.

  An object of the present invention is to provide an optical transmission apparatus, an optical transmission system, and an alarm issuing method that issue an alarm when transmission quality is deteriorated and a margin for error correction capability is lost.

  Another object of the present invention is to provide an optical transmission device, an optical transmission system, and an alarm issuing method that make it easy to identify the cause of a failure.

  Another object of the present invention is to provide an optical transmission device, an optical transmission system, and an alarm issuing method that generate few alarms at a time.

  Hereinafter, means for solving the problem will be described using the numbers and symbols used in [Best Mode for Carrying Out the Invention]. These numbers and symbols are added to clarify the correspondence between the description of [Claims] and [Best Mode for Carrying Out the Invention]. However, these numbers and symbols should not be used for the interpretation of the technical scope of the invention described in [Claims].

  In an aspect of the present invention, the optical transmission device includes a plurality of transponders (36) and an alarm control unit (37). The plurality of transponders (36) determine whether or not to issue a quality deterioration alarm indicating transmission quality deterioration based on the received data received from the transmission path. The alarm control unit (37) collects the issued quality deterioration alarms, and the quality of the transmission path is deteriorated based on the number of transponders issuing a quality deterioration alarm among the plurality of transponders (36). Controls the issuance of a transmission line quality degradation warning indicating that

  Each of the plurality of transponders (36) includes an FEC decoding unit (53), a first determination unit (55, 68), and a second determination unit (56, 66). A pre-correction quality deterioration warning and the post-correction quality deterioration warning are included. The FEC decoding unit (53) determines the transmission error of the received data based on the redundant data included in the received data, and corrects the transmission error detected as a result of the determination. The first determination unit (55, 68) determines whether a pre-correction quality deterioration alarm is issued based on the received data before the transmission error is corrected. The second determination unit (56, 66) determines whether a post-correction quality degradation alarm is issued based on the corrected received data whose transmission error has been corrected by the FEC decoding unit (53). The second determination unit (56, 66) notifies the transmission quality deterioration by using the corrected quality deterioration alarm as an individual quality deterioration alarm.

  Each of the plurality of transponders (36) includes a BIP verification unit (54, 65) for performing BIP (Bit Interleaved Parity) verification of an OTN (Optical Transport Network) layer based on the corrected received data. The second determination unit (56, 66) determines whether a post-correction quality degradation alarm is issued based on the number of errors detected by the BIP verification unit (54, 65).

  On the other hand, the first determination unit (55) determines the issue of the pre-correction quality deterioration alarm based on the number of errors detected by the FEC decoding unit (53). Alternatively, the first determination unit (68) is based on the number of errors detected by the second BIP verification unit (67) that performs BIP verification of the OTN layer based on the received data included in each of the plurality of transponders (36). You may determine the issuing of a quality deterioration alarm.

  The alarm control unit (37) issues a transmission line quality deterioration alarm when the number of transponders that issue a pre-correction quality deterioration alarm among the plurality of transponders (36) exceeds a predetermined threshold. Further, the alarm control unit (37) may control the plurality of transponders (36) so as not to issue the individual quality deterioration alarm from the plurality of transponders (36) when the transmission path quality deterioration alarm is issued. .

  These optical transmission devices are preferably wavelength division multiplexing (WDM) transmission devices, and each of the plurality of transponders (36) is a signal for each wavelength of the wavelength-multiplexed optical signal. Corresponding to Therefore, these determine the issue of a quality deterioration alarm based on the transmission quality for each wavelength.

  In another aspect of the present invention, the optical transmission system includes a transmitting terminal station (31) and a receiving terminal station (32). The transmitting terminal station (31) includes a plurality of transmitting side transponders (33). Each of the plurality of transmission side transponders (33) generates redundant data for detecting and correcting transmission errors based on the data to be transmitted, and sends the data to be transmitted and the redundant data to the transmission path as transmission data. The receiving terminal station (32) includes a plurality of receiving side transponders (36) and an alarm control unit (37). The plurality of reception side transponders (36) determine the presence or absence of a transmission error in the received data based on the redundant data included in the received data received from the transmission path. If there is a transmission error as a result of the determination, the receiving side transponder (36) corrects the detected transmission error and issues a quality deterioration alarm. The alarm control unit (37) determines the deterioration of the quality of the transmission line based on the number of reception side transponders that have issued the quality deterioration alarm in this way. If it is determined that the quality of the transmission path is significantly degraded, the alarm control unit (37) issues a transmission path quality degradation alarm indicating that the quality of the transmission path is degraded.

  The transmission-side transponder (33) of the present invention includes an FEC encoding unit (42) that generates redundant data based on data to be transmitted. On the other hand, the receiving-side transponder (36) includes an FEC decoding unit (53), a first determination unit (55, 68), and a second determination unit (56, 66). The FEC decoding unit (53) determines whether there is a transmission error in the received data based on the redundant data included in the received data. When it is determined that there is a transmission error, the FEC decoding unit (53) corrects the detected transmission error. The first determination unit (55, 68) determines whether a pre-correction quality deterioration alarm is issued based on the received data before the transmission error is corrected. The second determination unit (56, 66) determines whether a post-correction quality degradation alarm is issued based on the corrected received data whose transmission error has been corrected by the FEC decoding unit (53). Therefore, the quality deterioration alarm includes a pre-correction quality deterioration alarm and a post-correction quality deterioration alarm. Further, the second determination unit (56, 66) notifies the transmission quality deterioration by using the corrected quality deterioration alarm as an individual quality deterioration alarm.

  In addition, the receiving-side transponder (36) includes a BIP verification unit (54, 65) that performs OTN layer BIP verification based on the corrected received data. The second determination unit (56, 66) determines whether a post-correction quality degradation alarm is issued based on the number of errors detected by the BIP verification unit (54, 65).

  The first determination unit (55) determines whether a pre-correction quality deterioration alarm is issued based on the number of errors detected by the FEC decoding unit (53). In addition, the first determination unit (68) performs quality deterioration before correction based on the number of errors detected by the second BIP verification unit (67) that performs BIP verification of the OTN layer based on the reception data included in the reception-side transponder (36). The issue of an alarm may be determined.

  The alarm control unit (37) of the present invention issues a transmission line quality degradation alarm when the number of transponders that issue a quality degradation warning before correction out of the receiving transponders (36) exceeds a predetermined threshold. . At this time, the alarm control unit (37) may control the reception side transponder (36) so as not to issue an individual quality deterioration alarm from the reception side transponder (36).

  The optical transmission system of the present invention is preferably a WDM optical transmission system, and each of the reception side transponder (36) and the transmission side transponder (33) corresponds to a signal for each wavelength of the wavelength-multiplexed optical signal. To do. Therefore, when quality degradation is commonly occurring in a signal transmitted by one optical fiber, it is highly possible that some kind of failure has occurred in the optical fiber (transmission path), and an alarm is issued. The control unit (37) issues a transmission path quality deterioration alarm. When there is no commonality, the alarm control unit (37) estimates that a failure has occurred in a path for processing a signal of a wavelength having deteriorated.

  In another aspect of the present invention, the alarm issuing method includes a data transmission step, a data reception step, and an alarm control step. In the data transmission step, redundant data for detecting and correcting transmission errors is generated based on the data to be transmitted, and the data to be transmitted and the redundant data are transmitted to the transmission line as transmission data. The data receiving step determines whether there is a transmission error in the received data based on the redundant data included in the received data received from the transmission path. If a transmission error is detected, the data reception step corrects the transmission error and issues a quality deterioration alarm. The alarm control step controls the issuance of a transmission path quality degradation alarm indicating that the quality of the transmission path is degraded based on the number of transmission paths corresponding to the issuance of the quality degradation alarm.

  The data transmission step of the present invention includes an FEC encoding step for generating redundant data based on the data. The data receiving step includes an FEC decoding step, a first determination step, and a second determination step. The FEC decoding step determines the presence or absence of a transmission error in the received data based on the redundant data included in the received data, and corrects the detected transmission error if there is a transmission error. In the first determination step, it is determined whether a quality deterioration warning before correction is issued based on the received data before the transmission error is corrected. In the second determination step, it is determined whether or not a post-correction quality degradation alarm is issued based on the corrected received data in which the transmission error is corrected in the FEC decoding step. Therefore, the quality deterioration alarm includes a pre-correction quality deterioration alarm and a post-correction quality deterioration alarm. In the second determination step, transmission quality deterioration is notified using the corrected quality deterioration alarm as an individual quality deterioration alarm.

  The data reception step of the present invention includes a BIP verification step for performing BIP verification of the OTN layer based on the corrected received data. The second determination step determines whether a post-correction quality deterioration alarm is issued based on the number of errors detected in the BIP verification step.

  In the first determination step of the present invention, it is determined whether a quality deterioration warning before correction is issued based on the number of errors detected in the FEC decoding step. The first determination step may determine whether the pre-correction quality deterioration alarm is issued based on the number of errors detected in the second BIP collation step included in the data reception step. In this second BIP verification step, BTN verification of the OTN layer is performed based on the received data.

  The alarm control step of the present invention issues a transmission line quality deterioration alarm when the number of transmission lines corresponding to the issue of the quality correction alarm before correction exceeds a predetermined threshold.

  According to the present invention, it is possible to provide an optical transmission apparatus, an optical transmission system, and an alarm issuing method for issuing an alarm while a transmission quality is deteriorated but a margin for error correction capability remains.

  Furthermore, according to the present invention, it is possible to provide an optical transmission device, an optical transmission system, and an alarm issuing method that facilitate the isolation of the cause of a failure.

  Furthermore, according to the present invention, it is possible to provide an optical transmission apparatus, an optical transmission system, and an alarm issuing method that generate few alarms at a time.

  The best mode for carrying out the present invention will be described with reference to the drawings. FIG. 3 is a block diagram showing a configuration of a WDM (Wavelength Division Multiplexing) optical transmission system. In an optical transmission system, transmission apparatuses are installed opposite to each other, and data is transmitted and received bidirectionally by an optical signal transmitted on an optical transmission path (optical fiber) installed therebetween. Here, in order to simplify the explanation, transmission in only one direction will be taken up, and the transmission function and the reception function will be described separately.

  The section between the optical transmission terminal station 31 and the optical reception terminal station 32 is an ITU-T (International Telecommunication Union-Telecommunication Standardization Sector) recommendation G. This is a connection section of an OTN layer (Optical Transport Network) standardized by 709. As described in the background art with reference to FIG. 1, the OTN layer is located between the digital client layer and the optical medium that is a physical layer. The OTN layer has three layers: an optical channel layer (OCh layer), an optical multiplexing section layer (OMS layer), and an optical transmission section layer (OTS layer). The OCh layer provides end-to-end networking of optical channels that transparently transmit higher layer information (digital). The OMS layer provides a function of transmitting wavelength multiplexed optical signals (corresponding to a plurality of optical channels) through the wavelength multiplexing section. The OTS layer is located between the OMS layer and the optical medium, and provides a function of transmitting wavelength-multiplexed optical signals via various optical media.

  In the section of the OTN layer, transmission data error detection and correction are performed by the FEC (Forward Error Correction) method. Therefore, since “FEC layer = OTN layer”, the FEC layer is hereinafter referred to as an OTN layer.

  As shown in FIG. 3, the optical transmission system includes an optical transmission terminal station (transmission device) 31 including a plurality of transponders 33 and an optical multiplexing device (OMUX) 34, an optical demultiplexing device (ODMUX) 35, and a plurality of optical transmission / reception devices. The optical receiving terminal station (transmission device) 32 including the transponder 36 and the optical repeater station 38 including the optical amplifier in the transmission path therebetween.

  Each of the plurality of transponders 33 receives an electrical signal including data to be transmitted from a transmission-side client device (not shown), converts the electrical signal into an optical signal having an assigned wavelength, and outputs the optical signal to the optical multiplexing device 34. The optical multiplexer 34 multiplexes the optical signals input from the plurality of transponders 33 and outputs the multiplexed optical signals to the transmission path. Since the optical signal transmitted through the transmission line is attenuated in long-distance transmission, it is amplified by the optical amplifier of the optical repeater station 38 in the transmission line. The optical signal reaching the optical receiving terminal 32 is separated into optical signals for each wavelength by the optical demultiplexing device 35. The separated optical signal is output to the transponder 36 corresponding to the wavelength. The transponder 36 converts the input optical signal into an electrical signal, performs error detection correction based on the redundant information added by the optical transmission terminal station 31, and outputs the reception data to the receiving client device (not shown). To do. The alarm control unit 37 collects error information detected by each transponder 36 and outputs an alarm when necessary. In addition, transmission / reception with a client apparatus may be performed by an optical signal.

  As shown in FIG. 4, the transponder 33 of the optical transmission terminal station 31 includes an OTN BIP calculation unit 41, an FEC encoding unit 42, an FEC scramble unit 43, and an electrical / optical conversion unit 44.

  The OTN BIP calculation unit 41 performs a BIP (Bit Interleaved Parity) calculation, which is an error detection method for performing a parity check for each data block, on the transmission data of the OTN layer, and inserts the calculation result into the overhead. The FEC encoding unit 42 performs FEC encoding on the transmission data to which the BIP calculation result is assigned. The FEC scrambler 43 performs a scramble process on the transmission data using a predetermined generator polynomial for zero-continuous suppression. The electrical / optical conversion unit 44 converts the transmission data that has been scrambled, which is an electrical signal, into an optical signal and transmits the optical signal to the optical multiplexing device 34.

  As shown in FIG. 5, the transponder 36 of the optical receiving terminal 32 includes an optical / electrical conversion unit 51, an FEC descrambling unit 52, an FEC decoding unit 53, an OTN BIP verification unit 54, a DEG determination unit A55, and a DEG determination. Part B56 is provided.

  The optical / electrical converter 51 receives the optical signal from the optical demultiplexer 35 and converts it into an electrical signal. The FEC descramble unit 52 releases the scramble processed by the optical transmission terminal station 31. The FEC decoding unit 53 performs FEC decoding and outputs data after error detection and correction and the number of error corrections. The OTN BIP verification unit 54 compares the result of the BIP-8 operation on the FEC-decoded signal with the result of the BIP-8 operation inserted on the transmission side. The OTN BIP verification unit 54 detects a transmission error based on the comparison result and outputs the number.

  The DEG determination unit A55 determines the transmission quality before FEC correction based on the number of error corrections (that is, the number of transmission errors) output from the FEC decoding unit 53, and outputs a transmission quality deterioration alarm DEG1. The DEG determination unit B56 determines the transmission quality after the FEC correction based on the BIP-8 comparison result output from the OTN BIP verification unit 54, and outputs a transmission quality deterioration alarm DEG2. The alarm control unit 37 performs comprehensive evaluation based on the transmission quality deterioration alarm DEG1 and the transmission quality deterioration alarm DEG2 output from each transponder 36, and controls the issuing of the DEG alarm.

  Next, details of the operation of issuing an alarm will be described. The DEG determination unit A53 and the DEG determination unit B56 issue transmission quality deterioration alarms DEG1 and DEG2, as described below.

  The optical signal is input to the optical / electrical converter 51, and the received data converted into the electrical signal is output. If there is no error in the received data, or if the number of errors is equal to or less than the set threshold value, the DEG determination unit A53 and the DEG determination unit B56 do not issue a DEG alarm. When the transmission quality deteriorates and the error correction number (transmission error number) detected and corrected by the FEC decoding unit 53 exceeds the threshold set in the DEG determination unit A55, the DEG determination unit A55 A transmission quality deterioration alarm DEG1 is issued. At this time, if the transmission error is within the range of the error correction capability of the FEC decoding unit 53, all the transmission errors are corrected by the FEC decoding unit 53, so that the OTN BIP verification unit 54 does not detect the error. Become.

  When the transmission quality further deteriorates, an error exceeding the error correction capability of the FEC decoding unit 53 occurs. That is, an error exists in the data after the FEC correction. This is an error after the FEC correction, and the OTN BIP verification unit 54 detects this error. When the number of errors after the FEC correction detected by the OTN BIP verification unit 54 exceeds the threshold set in the DEG determination unit B56, the DEG determination unit B56 issues a transmission quality deterioration alarm DEG2 after the FEC correction. When the transmission quality deterioration alarm DEG2 is issued, a function of turning off the function of the transmission quality deterioration alarm DEG1 before the FEC correction may be provided. In that case, the transmission quality deterioration alarm DEG1 before the FEC correction is not issued.

  The optical transmitting terminal station 31 and the optical receiving terminal station 32 can simultaneously mount up to several hundreds of transponders 33 and 36 according to the number of wavelengths that can be multiplexed. In this case, when the quality of the transmission path deteriorates, a DEG alarm is issued from many of the mounted transponders. Therefore, maintenance tends to be complicated, such as fault isolation, fault location identification, and cause investigation.

  The alarm control unit 37 calculates the ratio of the transponders 36 that have issued the alarm based on the transmission quality deterioration alarm DEG1 indicating the transmission quality deterioration before the FEC correction, and sets it as the DEG1 occurrence rate. That is, the alarm control unit 37 determines the rate of occurrence of DEG1 (%) by (number of transponders 36 emitting transmission quality degradation alarm DEG1) / (total number of transponders 36 mounted on the optical receiving terminal 32) × 100. Is calculated. If the DEG1 occurrence rate exceeds a preset threshold, the alarm control unit 37 determines that there is a high possibility of transmission path deterioration, and outputs one DEG alarm as “transmission path DEG”. On the other hand, when the DEG1 occurrence rate is smaller than the threshold, there is a high possibility of deterioration due to the cause of each wavelength, and the alarm control unit 37 outputs a DEG alarm from each transponder 36 as “individual DEG”.

  When each transponder issues an individual DEG alarm based on the transmission quality degradation alarm DEG1, when the transmission quality degradation alarm DEG2 is not issued, this individual DEG alarm is an alarm indicating a sign of signal quality degradation at an individual wavelength. Become. Further, each transponder 36 may issue an individual DEG alarm based on the transmission quality deterioration alarm DEG2. In that case, it is possible to reduce the number of alarms issued.

  Here, the transmission line DEG is managed separately as an alarm of the OMS layer (ITU-T G.798 Optical Multiplex Section), and the individual DEG is managed separately as an alarm of the OCh layer (ITU-T G.798 Optical Channel). This management makes it possible to reduce the number of DEG alarms that are issued at one time, and to easily determine how to deal with each alarm. If it is a transmission line DEG, the WDM section is investigated such as transmission line dispersion measurement and optical amplifier input / output power measurement. If it is an individual DEG, conduct an individual investigation such as measuring the input / output power of the transponder of each wavelength that has issued an alarm. In this way, fault isolation becomes easy.

  At this time, if the alarm output from each transponder 36 as an individual DEG is the transmission quality deterioration alarm DEG2 after the FEC correction, the number of issues of the individual DEG can be reduced. Further, the alarm output as the individual DEG may be output via the alarm control unit 37 instead of directly from each transponder 36.

  Here, it has been described that the alarm generation is determined by calculating the DEG1 occurrence rate. However, the number of transponders issuing the transmission quality degradation alarm DEG1 to be transmitted from the transmission line DEG is set in advance as a threshold value. Also good.

  As described above, the transponder 36 includes the DEG determination unit A55 before FEC decoding (before correction) in addition to the DEG determination unit B56 included in the normal transmission apparatus. Therefore, the transmission quality deterioration alarm DEG1 determined from the transmission path error before the FEC correction is added to the conventional apparatus alarm. As a result, it is possible to issue an alarm according to the transmission quality degradation status. Further, the DEC determination unit A55 can turn on / off the transmission quality determination function, and can prevent the transmission quality deterioration alarm DEG1 from being issued. This transmission quality judgment function ON / OFF can be selected by the user. When the transmission quality determination function of the DEC determination unit A55 is off, only the general transmission quality deterioration alarm DEG2 after FEC correction is issued as usual.

  In the above embodiment, the transmission quality deterioration alarm DEG1 output from the DEG determination unit A55 and the transmission quality deterioration alarm DEG2 output from the DEG determination unit B56 are input from the respective transponders 36 to the alarm control unit 37 as they are. The transmission quality deterioration alarm DEG1 and the transmission quality deterioration alarm DEG2 may be obtained as a logical sum in the transponder 36, and the logical sum alarm may be output as a transmission quality deterioration alarm of the transponder 36. In that case, it becomes possible to warn in advance of the deterioration state of transmission quality without increasing the types of conventional alarms. In addition, since the change to add the type of alarm involves developing a new device, this simple implementation without increasing the type of alarm has an advantage in terms of development cost.

  Further, when the transmission quality deterioration alarm DEG2 is issued, it is considered that the transmission quality deterioration alarm DEG1 is always issued. Therefore, only the transmission quality deterioration alarm DEG1 may be used as the transmission quality deterioration alarm of the transponder 36. In that case, it becomes possible to warn in advance of the deterioration state of transmission quality without increasing the types of conventional alarms.

  Although the transmission quality degradation alarm DEG1 has been described as the number of errors at the time of FEC decoding, it is an alarm for monitoring the state before FEC correction. Therefore, the transmission quality deterioration alarm DEG1 may be issued based on other parameters whose transmission quality can be monitored. For example, the property that OTN layer BIP can be collated even before FEC decoding can be used. That is, like the standardized BIP verification after FEC correction, BIP verification is performed before FEC decoding, and the transmission quality is monitored by monitoring the result. In this case, as shown in FIG. 6, the transponder 36 includes an optical / electric conversion unit 61, an FEC descrambling unit 62, a branching unit 63, an FEC decoding unit 64, an OTN BIP verification unit 65, a DEG determination unit B66, and an OTN. A BIP verification unit 67 and a DEG determination unit A68 are provided.

  The optical / electrical converter 61 receives an optical signal from the transmission path and converts it into an electrical signal. The FEC descrambling unit 62 releases the scramble processed by the optical transmission terminal station. The branching unit 63 splits the descrambled electrical signal into two branches. The FEC decoding unit 64 performs FEC decoding, and performs error correction and output of the number of errors. The OTN BIP verification unit B65 compares the result of the BIP operation on the FEC-decoded signal with the result of the BIP operation inserted on the transmission side, and detects a transmission error. The DEG determination unit B66 determines whether the transmission quality deterioration alarm DEG2 after the FEC correction is issued based on the BIP-8 comparison result output from the BIP verification unit 65. The OTN BIP verification unit A67 compares the result of BIP calculation without descrambling the descrambled signal with the result of BIP calculation inserted on the transmission side, and detects a transmission error. The DEG determination unit A68 determines whether the transmission quality deterioration alarm DEG1 before FEC correction is issued based on the BIP-8 comparison result output from the BIP verification unit A67.

  As described above, when the transmission quality deterioration alarms DEG1 and DEG2 are input to the alarm control unit 37, the transmission path DEG alarm and the individual DEG alarm are issued based on them. Since this determination method is the same as described above, it is omitted.

  As described above, it is possible to know a margin decrease in transmission quality sufficiently before the issue of the DEG alarm after the FEC correction by the DEG alarm, so that various alarm actions and preventive measures can be taken. For example, when the transmission path is a transmission system having a protection (redundant) configuration, it is assumed that the transmission quality is slightly deteriorated. At this time, the signal is error-free by FEC correction. This deterioration is detected by the DEG determination unit A55 or the DEG determination unit A68, and a transmission quality deterioration alarm DEG1 before FEC correction is issued. This is collected from each transponder 36, and the alarm control unit 37 issues an alarm as the transmission path DEG when the number of transponders issuing the transmission quality deterioration alarm DEG1 exceeds a threshold value. Using this transmission path DEG alarm as a trigger, the optical receiving terminal station 32 and the optical transmitting terminal station 31 switch the transmission route to the standby system in advance. Since switching can be performed while there is a transmission quality margin, the signal can be relieved before the transmission quality is further deteriorated and the signal quality at the optical receiving terminal is affected.

  Similarly, in a transmission system including an optical amplifier capable of setting an amplification level, it is possible to detect in advance a deterioration in transmission quality. When a sign of deterioration is detected, the transmission system adjusts the amplification level of the optical amplifier to ensure a margin for error correction capability. Therefore, it is possible to relieve the signal before the transmission quality deteriorates as the error correction capability is exceeded and the signal quality at the optical receiving terminal is affected.

It is a figure which shows the layer structure of an optical transmission network. It is a figure explaining the relationship between FEC correction capability and a DEG alarm. It is a block diagram which shows the structure of the WDM optical transmission system which concerns on embodiment of this invention. It is a block diagram which shows the structure of the transponder of the optical transmission terminal station. It is a block diagram which shows the structure of the transponder of the same optical receiving terminal station. It is a block diagram which shows the other structure of the transponder of the same optical receiving terminal station.

Explanation of symbols

31 Optical transmitting terminal (transmission equipment)
32 Optical receiving terminal (transmission equipment)
33 Transponder 34 Optical multiplexer (OMUX)
35 Optical demultiplexer (ODMUX)
36 transponder 37 alarm control unit 38 optical repeater station 41 OTN BIP operation unit 42 FEC encoding unit 43 FEC scramble unit 44 electrical / optical conversion unit 51 optical / electrical conversion unit 52 FEC descrambling unit 53 FEC decoding unit 54 OTN BIP verification Part 55 DEG determination part A
56 DEG determination part B
61 Optical / Electric Converter 62 FEC Descrambler 63 Branching Unit 64 FEC Decoding Unit 65 OTN BIP Verification Unit 66 DEG Determination Unit B
67 OTN BIP verification unit 68 DEG determination unit A

Claims (22)

A plurality of transponders that determine the occurrence of a quality deterioration alarm indicating transmission quality deterioration based on received data received from the transmission path;
Collecting the quality degradation alarm and issuing a transmission path quality degradation alarm indicating that the quality of the transmission path is degraded based on the number of transponders issuing the quality degradation alarm among the plurality of transponders. An optical transmission device comprising: an alarm control unit for controlling. Each of the plurality of transponders is
An FEC decoding unit that determines a transmission error of the received data based on redundant data included in the received data and corrects the transmission error detected as a result of the determination;
A first determination unit that determines the issue of a quality deterioration warning before correction based on the received data before the transmission error is corrected;
A second determination unit that determines whether a post-correction quality degradation alarm is issued based on the corrected received data in which the transmission error is corrected by the FEC decoding unit, and
The second determination unit notifies the deterioration of transmission quality as an individual quality deterioration alarm using the corrected quality deterioration alarm,
The quality deterioration alarm includes the pre-correction quality deterioration alarm and the corrected quality deterioration alarm.
The optical transmission device according to claim 1. Each of the plurality of transponders includes a BIP verification unit that performs a BIP (Bit Interleaved Parity) verification of an OTN (Optical Transport Network) layer based on the corrected received data,
The optical transmission device according to claim 2, wherein the second determination unit determines whether the post-correction quality degradation alarm is issued based on the number of errors detected by the BIP verification unit. 4. The optical transmission device according to claim 2, wherein the first determination unit determines whether to issue the pre-correction quality deterioration alarm based on the number of errors detected by the FEC decoding unit. Each of the plurality of transponders includes a second BIP verification unit that performs OTN layer BIP verification based on the received data,
The optical transmission device according to claim 2 or 3, wherein the first determination unit determines whether the pre-correction quality deterioration alarm is issued based on the number of errors detected by the second BIP verification unit. The alarm control unit issues the transmission line quality deterioration alarm when the number of transponders that issue the pre-correction quality deterioration alarm among the plurality of transponders exceeds a predetermined threshold. 6. The optical transmission device according to any one of 5 above. The said alarm control part controls these transponders so that the said individual quality degradation alarm may not be emitted from these transponders, when the said transmission-line quality degradation alarm is issuing. An optical transmission device according to claim 1. 8. Each of the plurality of transponders corresponds to a signal for each wavelength of the wavelength-multiplexed optical signal, and determines whether the quality deterioration alarm is issued based on the transmission quality of the wavelength. An optical transmission device according to claim 1. A transmission terminal station comprising a plurality of transmission side transponders for generating redundant data for detecting and correcting transmission errors based on data to be transmitted, and sending the data and the redundant data as transmission data to a transmission path;
Determining a presence or absence of a transmission error in the received data based on the redundant data included in the received data received from the transmission path, and correcting the transmission error detected as a result of the determination and issuing a quality degradation alarm A receiving transponder;
An alarm control unit that controls the issuance of a transmission path quality degradation alarm indicating that the quality of the transmission path is degraded based on the number of the receiving-side transponders that have issued the quality degradation alarm. An optical transmission system comprising a station. The transmitting transponder is
An FEC encoder that generates the redundant data based on the data;
The receiving transponder is:
An FEC decoder that determines the presence or absence of a transmission error in the received data based on the redundant data included in the received data, and corrects the transmission error detected as a result of the determination;
A first determination unit that determines the occurrence of a pre-correction quality deterioration alarm based on the received data before the transmission error is corrected;
A second determination unit that determines whether a post-correction quality degradation alarm is issued based on the corrected received data in which the transmission error is corrected by the FEC decoding unit, and
The second determination unit notifies the deterioration of transmission quality as an individual quality deterioration alarm using the corrected quality deterioration alarm,
The optical transmission system according to claim 9, wherein the quality deterioration alarm includes the pre-correction quality deterioration alarm and the post-correction quality deterioration alarm. The receiving-side transponder includes a BIP verification unit that performs OIP layer BIP verification based on the corrected received data,
The optical transmission system according to claim 10, wherein the second determination unit determines whether the post-correction quality deterioration alarm is issued based on the number of errors detected by the BIP verification unit. The optical transmission system according to claim 10 or 11, wherein the first determination unit determines whether the pre-correction quality deterioration alarm is issued based on the number of errors detected by the FEC decoding unit. The receiving-side transponder includes a second BIP verification unit that performs OIP layer BIP verification based on the received data,
The optical transmission system according to claim 10 or 11, wherein the first determination unit determines whether the pre-correction quality deterioration alarm is issued based on the number of errors detected by the second BIP verification unit. The alarm control unit issues the transmission path quality degradation alarm when the number of transponders that issue the pre-correction quality degradation alarm among the receiving side transponders exceeds a predetermined threshold. Item 14. The optical transmission system according to Item 13. The said alarm control part controls the said receiving side transponder not to issue the said separate quality degradation alarm from the said receiving side transponder, when issuing the said transmission-line quality degradation warning. An optical transmission system according to claim 1. The optical transmission system according to any one of claims 9 to 15, wherein each of the reception-side transponder and the transmission-side transponder corresponds to a signal for each wavelength of the wavelength-multiplexed optical signal. A data transmission step of generating redundant data for transmission error detection and correction based on the data to be transmitted, and sending the data and the redundant data to the transmission line as transmission data;
Data reception for determining the presence or absence of a transmission error in the received data based on the redundant data included in the received data received from the transmission path, correcting the transmission error detected as a result of the determination, and issuing a quality deterioration alarm Steps,
An alarm control step for controlling the issuance of a transmission path quality degradation alarm indicating that the quality of the transmission path is degraded based on the number of transmission paths corresponding to the issuance of the quality degradation alarm. Method. The data transmission step includes:
FEC encoding step for generating the redundant data based on the data,
The data receiving step includes:
A FEC decoding step of determining the presence or absence of a transmission error in the reception data based on the redundant data included in the reception data and correcting the transmission error detected as a result of the determination;
A first determination step for determining the occurrence of a pre-correction quality degradation warning based on the received data before the transmission error is corrected;
A second determination step of determining whether a post-correction quality degradation alarm is issued based on the corrected received data in which the transmission error is corrected in the FEC decoding step;
In the second determination step, the post-correction quality deterioration alarm is used as an individual quality deterioration alarm to notify transmission quality deterioration,
The alarm issuing method according to claim 17, wherein the quality deterioration alarm includes the pre-correction quality deterioration alarm and the post-correction quality deterioration alarm. The data receiving step includes a BIP verification unit that performs BIP verification of the OTN layer based on the corrected received data,
The alarm issuing method according to claim 18, wherein the second determining step determines whether the corrected quality deterioration alarm is issued based on the number of errors detected in the BIP checking step. The alarm issuing method according to claim 18 or 19, wherein the first determining step determines whether to issue the pre-correction quality deterioration alarm based on the number of errors detected in the FEC decoding step. The data reception step includes a second BIP verification step of performing BTN verification of the OTN layer based on the received data,
The first determination step determines whether the pre-correction quality deterioration alarm is issued based on the number of errors detected in the second BIP collation step.
The alarm issuing method according to claim 18 or 19. The alarm control step issues the transmission line quality deterioration alarm when the number of the transmission lines corresponding to the issue of the quality deterioration alarm before correction exceeds a predetermined threshold. The alarm issuing method according to any one of the above.

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