JP2012023586A - Wavelength division multiplexing optical transmission/reception device and optical fiber misconnection detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wavelength division multiplexing optical transmission/reception device capable of easily detecting misconnection of an optical fiber when realizing a transmission/reception operation of a 10N GbE optical signal having the N-fold frequency of 10 G using N pieces of 10 GbE (Gigabit Ethernet) wavelength conversion units.SOLUTION: When an optical signal having the N-fold, e.g., 10-fold frequency of 10 G, that is, a 100 GbE optical signal from a client device 200 is converted into 10 pieces of 10 GbE optical signals by a 100 GbE <-> 10 GbE conversion unit 100 and input to 10 GbE wavelength conversion units 120-129 via 10 pieces of 10 GbE in-device optical fibers 140A-149A, each of the 10 GbE optical signals is composed of a signal obtained by applying block multiplexing to two-by-two PCS (Physical Coding Sublayer) lane signals grouped based on PCS lane numbers respectively and uniquely allocated to 2N pieces of PCS lane signals constituting the 100 GbE optical signal, and is transmitted via one 10 GbE in-device optical fiber mapped to the two-by-two PCS lane number allocated to each of the 10 GbE optical signals on a one-to-one basis.

Description

  The present invention relates to a wavelength division multiplexing optical transceiver and an optical fiber misconnection detection method.

  Along with the recent increase in capacity of information transmission, higher speed is demanded as a wavelength division multiplexing optical transmission system, and research and development of a 100 Gbps optical transmission system and a 40 Gbps optical transmission system are underway. The 100 Gbps optical transmission system requires an optical transceiver for wavelength division multiplexing (WDM) signals (that is, a 100 GbE wavelength converter) compatible with 100 GbE having a 100 GbE (100 Gigabit Ethernet (registered trademark)) optical transceiver as an interface. However, in order to realize error correction code processing, photoelectric conversion processing, long-distance optical transmission, and the like, optical / electrical components with a high degree of realization are required.

  As a method for realizing an optical transceiver for wavelength-division-multiplexed signals corresponding to 100 GbE like this, digital coherent reception technology is considered to be promising, but binary values that have been used in conventional optical transceivers for 10-Gbps wavelength-division-multiplexed signals Compared with the reception technique of the intensity modulation method, the configuration is complicated, the technical difficulty is high, and there are a plurality of problems for practical use.

  For this reason, for example, Japanese Laid-Open Patent Publication No. 2010-50803 “Optical transmission system” of Japanese Patent Application Laid-Open No. 2010-50803 until the above-described technology with a high degree of realization in a wavelength division multiplexing signal optical transceiver compatible with 100 GbE is put into practical use. It is effective to realize 10 Gbps long-distance optical transmission as 10 GbE optical transmission × 10 using the 10 GbE optical transmission technology that has already been commercialized. Thus, when realizing 100 GbE optical transmission using 10 GbE optical transmission × 10 pieces, for example, in an environment that already has 10 GbE transmission equipment (that is, 10 GbE wavelength conversion unit), 100 GbE long-distance transmission can be realized by newly developing and adding only a 100 GbE <-> 10 GbE conversion unit that bi-directionally converts a 10 GbE optical signal, which is preferable because it also reduces investment costs. .

JP 2010-50803 A (page 11-12)

  However, for connection between the 100 GbE <-> 10 GbE conversion unit and the 10 GbE wavelength conversion unit, it is necessary to connect 10 intra-device optical fibers and to connect the wavelength division multiplexing optical transceivers to each other. In addition, ten optical fibers between devices (wavelength division multiplexing optical signal transmission line: WDM transmission line) are required, and the connection of the optical fiber becomes complicated, which may cause an erroneous connection of the optical fiber. Therefore, a mechanism for detecting such an erroneous connection is required by monitoring the connection state of the optical fiber.

(Object of the present invention)
The present invention has been made in view of such circumstances, and an object of the present invention is to add a wavelength division multiplexing optical transceiver for a 10N GbE optical signal having a frequency N times 10 GbE to N 10 GbE wavelength conversion units ( To provide a wavelength division multiplexing optical transceiver and an optical fiber misconnection detection method capable of easily detecting an optical fiber misconnection when implemented using a 10 GbE wavelength division multiplexing optical signal transceiver. It is in.

  In order to solve the above-described problems, the wavelength division multiplexing optical transceiver and the optical fiber misconnection detection method according to the present invention mainly adopt the following characteristic configuration.

  (1) A wavelength division multiplexing optical transmission / reception apparatus according to the present invention transmits a 10N GbE optical signal having a frequency N times (N: positive integer) a 10 GbE (10 Gigabit Ethernet) optical signal transmitted from a client apparatus. <-> N wavelength-division multiplexing (WDM: Wavelength) by converting into 10 GbE optical signals by 10 GbE converters and input to N 10 GbE wavelength converters via N 10 GbE in-device optical fibers Division Multiplexing) N signals transmitted to the opposite device via N inter-device optical fibers and transmitted from the opposite device via N inter-device optical fibers N wavelength-division-multiplexed optical signals are input to the N 10 GbE wavelength converters to convert N 10 GbE optical signals via N optical fibers in the 10 GbE device. A wavelength division multiplexing optical transmitter / receiver for converting into a 10N GbE optical signal by being input to the 10N GbE <-> 10GbE converter and transmitting the optical signal to the client terminal, wherein the 10N GbE <-> 10GbE converter and the N Each of the N 10 GbE optical signals transmitted and received via each of the N 10 GbE in-device optical fibers connected to the 10 GbE wavelength converters of 2N PCS constituting the 10 N GbE optical signal (Physical Coding Sublayer) It is constituted by a signal obtained by block-multiplexing two PCS lane signals grouped on the basis of the PCS lane number uniquely assigned to each lane signal, and among the N optical fibers in the 10 GbE device, Two PCS lane numbers assigned to each 10 GbE optical signal Wherein the transmitting and receiving via the 10GbE device optical fiber associated with the to-1.

  (2) In the optical fiber misconnection detection method according to the present invention, a 10N GbE optical signal having a frequency N times (N: a positive integer) of a 10 GbE (10 Gigabit Ethernet) optical signal transmitted from a client device is converted to 10N GbE. <-> N wavelength-division multiplexing (WDM: Wavelength) by converting into 10 GbE optical signals by 10 GbE converters and input to N 10 GbE wavelength converters via N 10 GbE in-device optical fibers Division Multiplexing) N signals transmitted to the opposite device via N inter-device optical fibers and transmitted from the opposite device via N inter-device optical fibers N wavelength-division-multiplexed optical signals are input to the N 10 GbE wavelength converters to convert N 10 GbE optical signals via N optical fibers in the 10 GbE device. Incorrect connection of the 10GbE intra-apparatus optical fiber or the inter-apparatus optical fiber in the wavelength division multiplexing optical transceiver that inputs to the 10N GbE <-> 10GbE converter and converts it to a 10N GbE optical signal and transmits it to the client terminal An optical fiber misconnection detection method for detecting a 10G GbE <-> 10GbE conversion unit and N number of 10GbE wavelength conversion units connected to each of the N number of 10GbE in-device optical fibers. Each of the N 10 GbE optical signals to be transmitted and received are grouped based on PCS lane numbers uniquely assigned to 2N PCS (Physical Coding Sublayer) lane signals constituting the 10N GbE optical signal. Of the PCS lane signal is block-multiplexed, Among the optical fibers in the 0 GbE apparatus, by transmitting and receiving via the 10 GbE optical fibers in the 10 GbE apparatus one-to-one corresponding to the two PCS lane numbers allocated to the 10 GbE optical signals, An erroneous connection of an optical fiber or an inter-device optical fiber is detected.

  According to the wavelength division multiplexing optical transceiver and the optical fiber misconnection detection method of the present invention, the following effects can be obtained.

  That is, when a 10N GbE wavelength division multiplexing optical transceiver is configured using N (N: positive integer) 10 GbE wavelength converters, each of 2N PCS lane (Physical Coding Sublayer) signals constituting a 10N GbE optical signal. In N 10 GbE devices that configure N 10 GbE optical signals composed of PCS lane signals that are block-multiplexed two by two based on the PCS lane number assigned to each of the N 10 GbE optical signals. By performing one-to-one correspondence between an optical fiber and a PCS lane number assigned to each 10 GbE optical signal transmitted and received via each 10 GbE intra-apparatus optical fiber, each intra-apparatus optical fiber and inter-apparatus light 10GbE optical signals transmitted and received via fiber (WDM transmission line) and wavelength division multiplexing (W DM) Incorrect connection of 10GbE intra-apparatus optical fiber or inter-apparatus optical fiber (WDM transmission line) based on whether or not a PCS lane number mismatch is detected in the verification process of the PCS lane number attached to the optical signal Can be easily detected, and when an erroneous connection is detected, an alarm indicating that fact can be immediately issued to the maintenance person.

It is a block diagram which shows an example of the apparatus structure of the wavelength division multiplexing optical transmission / reception apparatus which concerns on this invention. FIG. 2 is a block configuration diagram illustrating an example of an internal configuration of a 100 GbE transmission-side PCS processing unit and a 100 GbE reception-side PCS processing unit of a 100 GbE <−> 10 GbE conversion unit in the wavelength division multiplexing optical transmission / reception apparatus illustrated in FIG. 1. When any of the 10 optical fibers in the 10 GbE device connecting the 100 GbE <-> 10 GbE converter and the 10 10 GbE wavelength converters in the wavelength division multiplexing optical transceiver shown in FIG. It is explanatory drawing for demonstrating an example of operation | movement of.

  Preferred embodiments of a wavelength division multiplexing optical transceiver and an optical fiber misconnection detection method according to the present invention will be described below with reference to the accompanying drawings.

(Features of the present invention)
Prior to the description of the embodiments of the present invention, an outline of the features of the present invention will be described first. The present invention provides a wavelength division multiplexing optical transmitter / receiver for a 10 N GbE optical signal having a frequency N times (N: positive integer) that of a 10 GbE optical signal in a 10 GbE (10 Gigabit Ethernet) optical transmission system currently in practical use. In the case of realization, the 10N GbE optical signal is converted into N 10GbE optical signals, and the converted N 10GbE optical signals are transmitted through N 10GbE optical fibers for transmitting and receiving N 10GbE optical signals. When constructing a mechanism for converting to N wavelength division multiplexing (WDM) signals by sending them to a 10 GbE wavelength conversion unit that has already been put into practical use, and transmitting / receiving to / from the opposite device, It was possible to easily detect erroneous connection of inter-device optical fiber (WDM transmission line) that connects between 10GbE intra-device optical fiber and opposing device. The door, are a major feature. For example, in the case of a 100 GbE (100 Gigabit Ethernet) optical signal currently being standardized by IEEE (Institute of Electrical and Electronics Engineers) 802.3ba, a 100 GbE optical signal is converted to 100 GbE <-> 10 GbE. Wavelength-division-multiplexed light that is converted into an optical signal equivalent to 10 GbE (10 Gigabit Ethernet), which has already been put into practical use, in the 10 GbE wavelength conversion unit. In a transmission / reception device, it is easy to erroneously connect an intra-device optical fiber that connects between a 100 GbE <-> 10 GbE conversion unit and a 10 GbE wavelength conversion unit and an inter-device optical fiber (WDM transmission line) that connects between opposing devices. The main feature is that it can be detected.

  In other words, in the present invention, the wavelength division multiplexing optical transceiver is composed of one 10N GbE <-> 10GbE converter and N 10GbE wavelength converters, and one 10N GbE <-> 10GbE converter. 2N PCS lane signals constituting a 10N GbE optical signal as a transmission side PCS (Physical Coding Sublayer) process in the case where N and 10 Nb 10GbE wavelength converters are connected by N 10GbE in-device optical fibers. Two PCS and one of the N 10 GbE intra-apparatus optical fibers are associated one by one with the PCS lane number assigned to each PCS lane signal, and the two PCSs associated with each other Means for distributing a 10 GbE signal composed of a lane signal to each optical fiber in the 10 GbE apparatus is provided. Also, as the PCS processing on the receiving side, the PCS lane number attached to each of the N 10 GbE signals transmitted from the N 10 GbE wavelength conversion units via the N optical fibers in the 10 GbE apparatus is transmitted to the transmitting side. The main feature is that it has means for determining whether or not the PCS lane number corresponds to the PCS lane number associated with each 10GbE intra-apparatus optical fiber in the PCS process.

(Description of configuration and operation of embodiment)
Next, a configuration example and an example of the operation of the wavelength division multiplexing optical transceiver according to the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing an example of a device configuration of a wavelength division multiplexing optical transceiver according to the present invention. In the following description of the embodiments, the case of N = 10 as a 10N GbE optical signal, that is, a case of a 100 GbE wavelength division multiplexing optical transceiver that transmits and receives a 100 GbE optical signal will be described as an example.

  1 includes one 100 GbE <-> 10 GbE conversion unit 100 and ten 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129. ing.

  The 100 GbE <-> 10 GbE conversion unit 100 transmits and receives a 100 GbE optical signal to and from the previous client apparatus 200. In addition, each of the 100 GbE <-> 10 GbE conversion unit 100 and the ten 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129 includes ten 10 GbE in-device optical fibers # 1 140A,. 10GbE optical signal # 1 140,..., 10GbE optical signal # 10 149 is transmitted / received by being connected by 10GbE in-device optical fiber # 10 149A. The 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129 are connected to the opposite device (opposing wavelength division multiplexing optical transmission / reception device). Ten WDM optical signals # 1 150,..., WDM optical signal # 10 159 are transmitted and received through each (Wavelength Division Multiplexing) transmission path.

  Further, the 100 GbE <-> 10 GbE conversion unit 100 converts the 10 GbE optical signals from the 100 GbE optical transceiver 101 and the 100 GbE optical transceiver 101 to perform photoelectric conversion between the 100 GbE optical signals and the 10 10 GbE electric signals, and 20 The PCS (Physical Coding Sublayer) lane signal is allocated to each of the 100 GbE transmission side PCS processing units 102 for generating 10 10 GbE signals each assigned with a PCS lane number assigned in advance. 10 GbE optical transceivers # 1 110,..., 10 GbE optical transceivers # 10 119 receive 10 GbE signals from the respective 10 GbE optical signals and perform reception processing corresponding to each PCS lane signal based on the PCS lane number to arrange 10 10 GbE electrical signals To generate 100GbE 100 GbE receiving side PCS processing unit 103 that outputs to the optical transceiver 101, 10 10 GbE optical transceivers # 1 110,..., 10 GbE optical transceiver # 10 that perform photoelectric conversion between 10 10 GbE optical signals and electrical signals, respectively 119.

  The 10 GbE wavelength converter # 1 120 encodes and decodes an error correction code of a 10 GbE optical transceiver 120 a and 10 GbE electrical signal that performs photoelectric conversion between the 10 GbE optical signal and the electrical signal. Decoding unit (FEC CODEC) 120b, wavelength conversion optical transceiver (λ1) 120c that performs photoelectric conversion between an optical signal for wavelength division multiplexing (WDM) and an electrical signal (λ1) 120c. I have. The remaining nine 10 GbE wavelength converters # 2 121,..., 10 GbE wavelength converter # 10 129 also have the same circuit configuration as the 10 GbE wavelength converter # 1 120.

  First, signal processing on the transmission side in the direction from the client device 200 to the opposite device (opposing wavelength division multiplexing optical transceiver) will be described. In the 100 GbE <-> 10 GbE converter 100 that has received the 100 GbE optical signal 130 from the client device 200, the 100 GbE optical transceiver 101 converts the received 100 GbE optical signal 130 into ten 10 GbE electrical signals. Thereafter, the 10 converted 10 GbE electric signals are divided into 20 PCS (Physical Coding Sublayer) lane signals in the 100 GbE transmission side PCS processing unit 102 by using 64B / 66B codes as they are and making blocks of 66 bits. At the same time, by absorbing the skew difference of the 20 PCS lane signals constituting the 100 GbE signal, aligning the PCS lane signals, and performing 66B block multiplexing on each of the 20 PCS lane signals, One 10 GbE electrical signal is generated one by one, and a total of 10 10 GbE electrical signals are generated.

  Here, in the 100 GbE transmitting-side PCS processing unit 102, 10 GbE optical signals # 1 140A,..., 10 GbE in-device optical fibers # 10 149A, that is, 10 GbE optical signals # 1 140, ..., for each 10 GbE electrical signal (a signal obtained by block-multiplexing two PCS lane signals) corresponding to each 10 GbE optical signal # 10 149, a predetermined unique PCS lane among the 20 PCS lane numbers. Two numbers will be assigned. For example, two PCS lane numbers “0” and “1” are assigned to the 10 GbE electrical signal corresponding to the 10 GbE optical signal # 1 140 transmitted to the 10 GbE in-device optical fiber # 1 140A,..., The last PCS lane Two numbers “18” and “19” are assigned to the 10 GbE electrical signal corresponding to the 10 GbE optical signal # 10 149 transmitted to the optical fiber # 10 149A in the 10 GbE device.

  Ten 10 GbE optical signals generated by the 100 GbE transmitting-side PCS processing unit 102 are converted into ten 10 GbE optical signals, that is, 10 GbE optical signals by ten 10 GbE optical transceivers # 1 110,..., 10 GbE optical transceiver # 10 119, respectively. # 1 140,..., 10GbE optical signal # 10 149, converted into 10 10GbE wavelength conversions via 10 optical fibers # 1 140A, 10GbE in-device optical fiber # 10 149A, respectively. Unit # 1 120,..., 10 GbE wavelength conversion unit # 10 129.

  Each of the 10 GbE wavelength converters # 1 120,..., 10GbE wavelength converter # 10 129 receives 10 received 10 GbE optical signals # 1 140,..., 10 GbE optical signals # 10 149, respectively. WDM optical signal # 1 150,..., WDM optical signal # 10 159 are converted into wavelengths, and transmitted to the opposite device via 10 inter-device optical fibers, that is, WDM transmission lines.

  That is, among the 10 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129, for example, in the 10 GbE wavelength conversion unit # 1 120, the received 10 GbE optical signal # 1 140 is transferred to the 10 GbE optical transceiver 120a. Is converted into an electric signal. The converted electrical signal is encoded with an error correction code in the error correction encoding / decoding unit 120b, and then the WDM optical signal # 1 150 adapted to the WDM wavelength grid (λ1) by the wavelength conversion optical transceiver 120c. The wavelength is converted into an optical fiber between the devices, that is, transmitted to the WDM transmission line.

  The same applies to the remaining nine 10 GbE wavelength converters # 2 121,..., 10 GbE wavelength converter # 10 129, and the electrical corresponding to each of the received 10 GbE optical signals # 2 141,. After the conversion to the signal, the error correction code relating to each electric signal is encoded, and then the WDM optical signal # 2 151,..., WDM adapted to the corresponding WDM wavelength grid (λ2,..., Λ10). The optical signal # 10 159 is wavelength-converted and transmitted to each inter-device optical fiber, that is, a WDM transmission line.

  Next, signal processing on the receiving side in the direction from the opposite device (opposing wavelength division multiplexing optical transmission / reception device) to the client device 200 will be described. In each of the 10 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129, 10 WDMs transmitted from the opposite device via 10 inter-device optical fibers, that is, WDM transmission lines, respectively. , WDM optical signal # 10 159 is converted into ten 10 GbE optical signals, and 10 10 GbE in-device optical fibers # 1 140A,..., 10 GbE in-device optical fibers # 10 149A Process to send to each.

  That is, among the 10 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129, for example, the 10 GbE wavelength conversion unit # 1 120 uses the received WDM optical signal # 1 150 for wavelength conversion. An optical signal is converted by the optical transceiver 120c. The converted electrical signal is decoded by the error correction encoding / decoding unit 120b and then converted to the 10 GbE optical signal # 1 140 by the 10 GbE optical transceiver 120a, and the optical fiber # in the 10 GbE device # 1 sent to 140A.

  The same applies to the remaining nine 10 GbE wavelength conversion units # 2 121,..., 10 GbE wavelength conversion unit # 10 129, and each corresponds to the received WDM optical signal # 2 151,. After being converted into electrical signals, the error correction codes relating to the respective electrical signals are decoded, and then converted into 10 GbE optical signals # 2 141,..., 10 GbE optical signals # 10 149, respectively, , 10GbE in-device optical fiber # 2 141A,..., 10 GbE in-device optical fiber # 10 149A.

  .. 10GbE optical fiber # 1 140A,..., 10GbE optical fiber # 10 149A received 10 GbE optical signals # 1 140,..., 10GbE optical signal # 10 149 from 100 GbE <-> In the 10 GbE converter 100, the received 10 GbE optical signals # 1 140,..., 10 GbE optical signals # 10 149 are converted into electrical signals in the 10 10 GbE optical transceivers 110,. Thereafter, the converted electrical signal is subjected to reception processing related to the signal that has been distributed to a total of 20 PCS lane signals as a 66-bit block using the 64B / 66B code as it is in the 100 GbE reception-side PCS processing unit 103. At the same time, the skew difference of a total of 20 PCS lane signals for constituting a 100 GbE signal is absorbed.

  Here, when the skew difference absorption processing (deskew) is performed, the PCS lane number assigned to each 10 GbE electrical signal corresponding to each 10 GbE optical signal # 1 140,..., 10 GbE optical signal # 10 149 The PCS lane number corresponding to the unique PCS lane number assigned in advance in the 100 GbE transmission-side PCS processing unit 102 is confirmed. In other words, each 10 GbE optical signal # 1 140,..., 10 GbE optical signal # 10 149 received via each 10 GbE intra-apparatus optical fiber # 1 140A,. The unit 102 confirms whether or not the data has been transmitted via the 10 GbE in-device optical fiber that has been decided in advance.

  As described above, in the 100 GbE transmission-side PCS processing unit 102, for example, two PCS lane numbers “0” and “1” are transmitted to the 10 GbE optical signal # 1 140 transmitted to the 10 GbE intra-apparatus optical fiber # 1 140A. The last two PCS lane numbers '18' and '19' are assigned to the corresponding 10GbE electrical signal, and the 10GbE electrical signal # 10 149 transmitted to the 10GbE in-device optical fiber # 10 149A is 10GbE electrical. Assigned to the signal.

  Therefore, in the 100 GbE receiving-side PCS processing unit 103, for example, two of the PCS lane numbers “0” and “1” are assigned via the 10 GbE intra-apparatus optical fiber # 1 140 </ b> A previously assigned in the 100 GbE transmitting-side PCS processing unit 102. When the 10GbE electrical signal corresponding to the received 10GbE optical signal # 1 140 is given two PCS lane numbers “0” and “1”, a normal inter-device optical fiber (WDM transmission line) And a 10 GbE electrical signal corresponding to the 10 GbE optical signal # 1 140 received via the 10 GbE in-device optical fiber. On the other hand, when a PCS lane number different from “0” and “1” is assigned, the reception is via the wrong inter-device optical fiber (WDM transmission line) or 10 GbE in-device optical fiber. Then, it is determined that the inter-device optical fiber (WDM transmission line) or the 10 GbE intra-device optical fiber connection is incorrect, and an alarm indicating that the optical fiber is erroneously connected is issued.

  After confirming the normality of connection between the inter-device optical fiber (WDM transmission line) and the 10 GbE intra-device optical fiber based on the PCS lane number match check, absorb the skew difference (deskew) of each PCS lane. Align the PCS lane signals and generate 10 10GbE electrical signals. The 10 generated 10 GbE electrical signals are converted into 100 GbE optical signals 130 by the 100 GbE optical transceiver 101 and transmitted to the client device 200.

  Next, an example of the internal configuration of the 100 GbE transmission side PCS processing unit 102 and the 100 GbE reception side PCS processing unit 103 of the 100 GbE <-> 10 GbE conversion unit 100 will be described with reference to FIG. FIG. 2 is a block diagram illustrating an example of the internal configuration of the 100 GbE transmission-side PCS processing unit 102 and the 100 GbE reception-side PCS processing unit 103 of the 100 GbE <−> 10 GbE conversion unit 100 in the wavelength division multiplexing optical transmission / reception apparatus illustrated in FIG. 2, the upper side of FIG. 2 shows a block configuration example of the 100 GbE transmission side PCS processing unit 102, and the lower side of FIG. 2 shows a block configuration example of the 100 GbE reception side PCS processing unit 103.

  In FIG. 2, the 100 GbE transmission-side PCS processing unit 102 includes a 1: 2SP conversion unit 201, a 66B block synchronization unit 202, an alignment marker detection unit 203, a skew adjustment unit 204, a PCS lane alignment unit 205, a PCS lane distribution unit 206, 2: 1 PS conversion unit 207 is configured to include at least a 100 GbE reception-side PCS processing unit 103, a 1: 2SP conversion unit 211, a 66B block synchronization unit 212, an alignment marker detection unit 213, a PCS lane number match detection unit 214, A skew adjustment unit 215, a PCS lane alignment unit 216, and a 2: 1 PS conversion unit 217 are provided at least.

  First, an example of the internal configuration of the 100 GbE transmission-side PCS processing unit 102 will be described. The 100 GbE signal is input as 10.103125 Gbps electrical signals × 10 from the 100 GbE optical transceiver 101, and is converted into 5.15625 Gbps signals × 20 by the 1: 2SP conversion unit 201. At this time, each of the 20 5.15625 Gbps signals becomes one PCS lane signal, and a total of 20 PCS lane signals are formed.

  For each of the 20 PCS lane signals, the 66B block synchronization unit 202 detects the start position of the 64B / 66B code (that is, the Sync Header position of the 64B / 66B code). When the head positions of the 64B / 66B codes of the 20 PCS lane signals are detected, the alignment marker detection unit 203 compares the PCS lane numbers of the 20 PCS lane signals and the phases between the PCS lanes. Thus, a skew difference between the PCS lane signals is detected.

  When a skew difference between the PCS lane signals is detected, the skew adjustment unit 204 inserts a delay corresponding to the skew difference of each of the 20 PCS lane signals into each PCS lane signal, thereby obtaining 20 PCS lane signals. The skew difference between signals is reduced to zero to eliminate the skew difference.

  After the skew difference between the 20 PCS lane signals is set to zero, the PCS lane aligning unit 205 logically arranges the 20 PCS lane signals in the order of the PCS lane numbers, thereby logically serializing the 100 GbE signal. To do.

  The 20 PCS lane signals that have been logically serialized are grouped together in the order of the serialized PCS lane numbers, and the PCS lane distribution unit 206 multiplexes 64B / 66B code units. At this time, for example, the PCS lane numbers “0” and “1” correspond to the 10.103125 Gbps signals so that the 20 PCS lane numbers have a 1: 1 correspondence with 10 10.125 Gbps signals. Rules such as the first and the last “18” and “19” of the PCS lane number are set to the tenth of the 10.12525 Gbps signal in advance. The multiplexed signals are each converted into a 10.12525 Gbps signal in the 2: 1 SP conversion unit 207, and are generated as a total of 10.103125 Gbps signals from the first to the tenth, and then 10 signals in the subsequent stage. , And 10 GbE optical transceiver # 10 119, respectively.

  Next, an internal configuration example of the 100 GbE reception-side PCS processing unit 103 will be described. The 10 10.125 Gbps electrical signals transmitted from each of the 10 10 GbE optical transceivers # 1 110,..., 10 GbE optical transceiver # 10 119 are converted into 5.15625 Gbps signals × 20 by the 1: 2SP converter 211. Converted. At this time, each of the 20 5.15625 Gbps signals becomes one PCS lane signal, and a total of 20 PCS lane signals are formed.

  For each of the 20 PCS lane signals, the 66B block synchronization unit 212 detects the start position of the 64B / 66B code (that is, the Sync Header position of the 64B / 66B code). When the start positions of the 64B / 66B codes of the 20 PCS lane signals are detected, the alignment marker detection unit 213 compares the PCS lane numbers of the 20 PCS lane signals and the phases between the PCS lanes. Thus, a skew difference between the PCS lane signals is detected.

  Further, a skew difference between the PCS lane signals is detected, and on the basis of the detected PCS lane number, the PCS lane number coincidence detection unit 214 performs pairing in the PCS lane distribution unit 206 of the 100 GbE transmission side PCS processing unit 102. It is checked whether or not the PCS lane number should be obtained from the 10.12525 Gbps signal assigned in association with 1. If the check result does not match, for example, if the PCS lane number that should be obtained from the first 10.3125 Gbps signal is '18' and '19' instead of '0' and '1' , An alarm indicating a mismatch is issued, that is, it is determined that the connection of the 10 GbE intra-apparatus optical fiber or inter-apparatus optical fiber (WDM transmission line) is incorrect, and the 10 GbE intra-apparatus optical fiber or inter-apparatus light An alarm indicating that the optical fiber in the fiber (WDM transmission line) is erroneously connected is issued and notified to the maintenance personnel.

  After the PCS lane number coincidence determination with respect to 10 10.12525 Gbps signals corresponding to each of the 20 PCS lane signals, the skew adjustment unit 215 performs a delay corresponding to the skew difference of each of the 20 PCS lane signals. By inserting each PCS lane signal, the skew difference between the 20 PCS lane signals is made zero, and the skew difference is eliminated.

  After the skew difference between the 20 PCS lane signals is set to zero, the PCS lane alignment unit 216 logically arranges the 20 PCS lane signals in the order of the PCS lane numbers, thereby logically serializing the 100 GbE signal. To do.

  Thereafter, the 20 PCS lane signals that have been logically serialized are collected by the 2: 1 SP converter 217 in the order of the serialized PCS lane numbers, and converted into 10.253 Gbps signals. Are converted into a total of 10.103125 Gbps signals and output to the subsequent 100 GbE optical transceiver 101.

  As described above, at the signal processing level of the PCS lane signal, the PCS lane numbers of the 20 PCS lane signals constituting the 100 GbE signal are associated with the 10 GbE intra-device optical fiber and the inter-device optical fiber (WDM transmission line). It is possible to easily check the normality of the connection between the 10 GbE intra-apparatus optical fiber and the inter-apparatus optical fiber (WDM transmission line), and the 10 GbE intra-apparatus optical fiber or inter-apparatus optical fiber (WDM transmission line) When an incorrect connection is detected, an alarm to that effect is issued to the maintenance person.

  That is, in the PCS lane distribution unit 206 of the 100 GbE transmission-side PCS processing unit 102, two PCS lane signals out of the 20 PCS lane signals constituting the 100 GbE signal and ten 10 GbE in-device optical fibers (that is, , 100 GbE <-> 10 GbE converter 100 and 10 10 GbE wavelength converters # 1 120,..., 10 GbE wavelength converter # 10 129, respectively, 10 10 GbE in-device optical fibers # 1 140 A,. , 10GbE in-device optical fiber # 10 149A), one 10GbE in-device optical fiber is associated one-to-one with each PCS lane number, and two 20 PCS lane signals are provided Each of the 10 optical fibers in the 10 GbE device is distributed.

  On the other hand, in the PCS lane number coincidence detecting unit 214 of the 100 GbE receiving-side PCS processing unit 103, ten 10 GbE wavelength converting units # 1 120,..., 10 GbE wavelength converting unit # 10 129 to ten 10 GbE in-device optical fibers respectively. Whether the PCS lane numbers of the 10 10GbE signals received via the PCS lane numbers corresponding to the PCS lane numbers assigned by the PCS lane assignment unit 206 of the 100GbE transmission side PCS processing unit 102 are attached. Determine. If the PCS lane number assigned to each received 10 GbE signal matches the PCS lane number assigned by the PCS lane assignment unit 206, the corresponding 10 GbE intra-apparatus optical fiber and inter-apparatus optical fiber are connected normally. If they are in a state and do not match, an alarm is issued to the maintenance person because the corresponding 10 GbE intra-apparatus optical fiber or inter-apparatus optical fiber is misconnected.

  Next, with respect to any of the ten 10 GbE in-device optical fibers, an operation in the case where an erroneous connection is made will be further connected using FIG. 3 connects between the 100 GbE <-> 10 GbE converter 100 and the 10 GbE wavelength converters # 1 120,..., 10 GbE wavelength converter # 10 129 in the wavelength division multiplexing optical transceiver shown in FIG. It is explanatory drawing for demonstrating an example of operation | movement when any of 10 optical fiber # 1 140A in 10GbE apparatus # ... 140A optical fiber # 10 149A in 10GbE apparatus has an incorrect connection. In FIG. 3, among the 10 optical fibers in the 10 GbE device, the transmission light of the optical fiber # 1 140A in the 10 GbE device from the 100 GbE <-> 10 GbE conversion unit 100 to the first 10 GbE wavelength conversion unit # 1 120 A case where the fiber and the transmission optical fiber of the 10 GbE in-device optical fiber # 10 149A from the 100 GbE <-> 10 GbE conversion unit 100 to the tenth 10 GbE wavelength conversion unit # 10 129 are switched in a wrong state. Shown for example.

  In the explanatory diagram of FIG. 3, the inter-device optical fiber (WDM transmission line) for connecting the wavelength division multiplexing optical transmission / reception device and the wavelength division multiplexing optical transmission / reception device on the opposite device side (the counterpart side) and the opposite device are provided. It is assumed that all the 10 GbE intra-apparatus optical fibers in the wavelength division multiplexing optical transmission / reception apparatus on the side (partner side) are connected in a normal state. In addition, the correspondence between the 10.125125 Gbps signal and the PCS lane number is as follows. For the first 10.125125 Gbps signal, “0” and “1” are assigned as the PCS lane numbers. , The third PCS lane number is assigned, and the last tenth 10.125125 Gbps signal is assigned with “18” and “19” as the PCS lane number.

  When there is an erroneous connection of the optical fiber in the 10 GbE device as shown in FIG. 3, WDM optical signal # 1 150,..., WDM optical signal # 10 159 is transmitted from the wavelength division multiplexing optical transceiver. In the 100 GbE receiving-side PCS processing unit 103 on the wavelength division multiplexing optical transceiver on the opposite device side, '18' and '19' are detected as PCS lane numbers from the first 10.12525 Gbps signal, Also, “0” and “1” are detected as PCS lane numbers from the 10th 10.125125 Gbps signal. Therefore, the PCS lane number coincidence detection unit 214 of the 100 GbE receiving side PCS processing unit 103 does not coincide with the PCS lane number coincidence determination result, that is, the PCS lane number inconsistency alarm, that is, the first in-device optical fiber # 1 140A. In addition, an alarm indicating that an erroneous connection of the tenth in-device optical fiber # 10 149A has been detected is issued.

  As described above, in the wavelength division multiplexing optical transceiver shown in FIGS. 1 and 2, the 100 GbE <-> 10 GbE conversion unit 100 and the 10 10 GbE wavelength conversion units # 1 120,..., 10 GbE wavelength conversion unit # 10 129 , And 10 GbE in-device optical fiber # 1 140A,..., 10 GbE in-device optical fiber # 10 149A, respectively. As the PCS processing on the transmission side, two of the 20 PCS lane signals constituting the 100 GbE signal and one of the 10 optical fibers in the 10 GbE device are one-to-one based on the PCS lane number. Associating and distributing, 10 G of 10G as the receiving PCS processing of the 100 GbE receiving PCS processing unit 103 E wavelength converter # 1 120,..., 10 GbE wavelength converter # 10 The PCS lane number attached to each of the 10 GbE signals received via each of the 10 GbE in-device optical fibers from 10 129 is 100 GbE. Connection of ten 10 GbE intra-apparatus optical fibers and inter-apparatus optical fibers (WDM transmission lines) by determining whether the PCS lane number should have been allocated in the transmission-side PCS processing of the transmission-side PCS processing unit 102 It is possible to easily detect the normality of.

  In the wavelength division multiplexing optical transmitter / receiver shown in FIGS. 1 to 3, the case of transmitting / receiving a 100 GbE optical signal has been shown. However, the present invention is not limited to such a case, and is standardized in IEEE, for example. The 40 GbE wavelength division multiplexing optical transmitter / receiver that is going to be used has the same configuration as that shown in FIGS. 1 to 3 except that the number of PCS lanes is changed from 10 to 4, thereby providing 10 GbE. Needless to say, it is possible to easily detect an erroneous connection between the intra-device optical fiber and the inter-device optical fiber (WDM transmission line).

(Description of the effect of this embodiment)
As described in detail above, the following effects are obtained in the present embodiment. That is, when a 10N GbE wavelength division multiplexing optical transceiver is configured using N (N: positive integer) 10 GbE wavelength converters, each of 2N PCS lane (Physical Coding Sublayer) signals constituting a 10N GbE optical signal. In N 10 GbE devices that configure N 10 GbE optical signals composed of PCS lane signals that are block-multiplexed two by two based on the PCS lane number assigned to each of the N 10 GbE optical signals. By performing one-to-one correspondence between an optical fiber and a PCS lane number assigned to each 10 GbE optical signal transmitted and received via each 10 GbE intra-apparatus optical fiber, each intra-apparatus optical fiber and inter-apparatus light 10GbE optical signals transmitted and received via fiber (WDM transmission line) and wavelength division multiplexing (W M) Incorrect connection of 10GbE intra-apparatus optical fiber or inter-apparatus optical fiber (WDM transmission line) based on whether or not a PCS lane number mismatch is detected in the verification process of the PCS lane number attached to the optical signal Can be easily detected, and when an erroneous connection is detected, an alarm indicating that fact can be immediately issued to the maintenance person.

  The configuration of the preferred embodiment of the present invention has been described above. However, it should be noted that such examples are merely illustrative of the invention and do not limit the invention in any way. Those skilled in the art will readily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention.

100 100 GbE <-> 10 GbE conversion unit 101 100 GbE optical transceiver 102 100 GbE transmission side PCS processing unit 103 100 GbE reception side PCS processing unit 110 10 GbE optical transceiver # 1
111 10GbE optical transceiver # 2
119 10GbE optical transceiver # 10
120 10 GbE wavelength converter # 1
120a 10GbE optical transceiver 120b Error correction encoding / decoding unit (FEC CODEC)
120c Optical transceiver for wavelength conversion (λ1)
121 10 GbE wavelength converter # 2
129 10 GbE wavelength converter # 10
130 100 GbE optical signal 140 A 10 GbE in-device optical fiber # 1
141A 10GbE in-device optical fiber # 2
149A 10GbE in-device optical fiber # 10
140 10 GbE optical signal # 1
141 10 GbE optical signal # 2
149 10 GbE optical signal # 10
150 WDM optical signal # 1
151 WDM optical signal # 2
159 Optical signal # 10 for WDM
200 Client device 201 1: 2SP conversion unit 202 66B block synchronization unit 203 Alignment marker detection unit 204 Skew adjustment unit 205 PCS lane alignment unit 206 PCS lane distribution unit 207 2: 1 PS conversion unit 211 1: 2SP conversion unit 212 66B block synchronization Unit 213 alignment marker detection unit 214 PCS lane number coincidence detection unit 215 skew adjustment unit 216 PCS lane alignment unit 217 2: 1 PS conversion unit

Claims (8)

  A 10N GbE optical signal having a frequency N times (N: positive integer) of a 10 GbE (10 Gigabit Ethernet) optical signal transmitted from the client device is converted into N 10 GbE optical signals by a 10N GbE <-> 10 GbE conversion unit. By converting it and inputting it to N 10 GbE wavelength converters via N 10 GbE intra-apparatus optical fibers, it is converted into N wavelength division multiplexing (WDM) optical signals to the opposite device. N wavelength division multiplexed optical signals transmitted via N inter-device optical fibers and transmitted from the opposite device via N inter-device optical fibers are converted into N 10 GbE wavelength conversions. N 10 GbE optical signals that are input and converted are input to the 10 N GbE <-> 10 GbE conversion unit via N optical fibers in the 10 GbE apparatus. A wavelength division multiplexing optical transceiver that converts the optical signal into a 10N GbE optical signal and transmits the optical signal to the client terminal, and connects the 10N GbE <-> 10GbE converter and the N 10GbE wavelength converters Each of the N 10 GbE optical signals transmitted and received via each of the N 10 GbE intra-apparatus optical fibers is unique to each of 2N PCS (Physical Coding Sublayer) lane signals constituting the 10 N GbE optical signal. Two PCS lane signals grouped on the basis of the assigned PCS lane number are configured by signals obtained by block multiplexing, and two of each of the 10 GbE optical fibers in the 10 GbE optical fiber allocated to each of the 10 GbE optical signals. The 10GbE intra-device optical fiber associated with the PCS lane number on a one-to-one basis Wavelength division multiplexing optical transceiver, characterized by transmitting and receiving through.   As the transmission-side PCS processing in the 10N GbE <-> 10GbE converter, each of the two PCS lane signals is specific to each of the N 10 GbE optical signals each composed of two PCS lane signals. One of the 10 GbE intra-apparatus optical fibers associated with the two PCS lane numbers on a one-to-one basis among the N ten-GbE intra-apparatus optical fibers with the assigned PCS lane number The 10 GbE optical signals are respectively transmitted through the N, the N 10 GbE wavelength converters convert the N wavelength divided multiplexed optical signals into the N wavelength-division-multiplexed optical signals, and the N optical fibers are connected via the inter-device optical fibers. The wavelength division multiplexing optical transceiver according to claim 1, wherein the wavelength-division multiplexed optical transceiver is transmitted to the apparatus.   As the reception-side PCS processing in the 10N GbE <-> 10GbE conversion unit, N wavelength division multiplexed optical signals received from the opposite device via the N inter-device optical fibers are converted to obtain the N The PCS lane number assigned to each of the N 10 GbE optical signals transmitted through each 10 GbE intra-apparatus optical fiber, and a pair of each of the N inter-apparatus optical fibers as the transmission side PCS processing If the PCS lane number assigned to each of the N 10 GbE optical signals corresponding to 1 is compared and does not match, there is an error in the 10 GbE intra-apparatus optical fiber or the inter-apparatus optical fiber. 3. The wavelength division multiplexing optical transceiver according to claim 2, wherein an alarm indicating that there is a connection is issued to a maintenance person.   4. The wavelength division multiplexing optical transceiver according to claim 1, wherein the 10N GbE optical signal is a 100 GbE optical signal or a 40 GbE optical signal. 5.   A 10N GbE optical signal having a frequency N times (N: positive integer) of a 10 GbE (10 Gigabit Ethernet) optical signal transmitted from the client device is converted into N 10 GbE optical signals by a 10N GbE <-> 10 GbE conversion unit. By converting it and inputting it to N 10 GbE wavelength converters via N 10 GbE intra-apparatus optical fibers, it is converted into N wavelength division multiplexing (WDM) optical signals to the opposite device. N wavelength division multiplexed optical signals transmitted via N inter-device optical fibers and transmitted from the opposite device via N inter-device optical fibers are converted into N 10 GbE wavelength conversions. N 10 GbE optical signals that are input and converted are input to the 10 N GbE <-> 10 GbE conversion unit via N optical fibers in the 10 GbE apparatus. An optical fiber misconnection detection method for detecting an erroneous connection of an optical fiber in the 10 GbE device or an optical fiber between devices in a wavelength division multiplexing optical transceiver that converts the optical signal into a 10 N GbE optical signal and transmits the optical signal to the client terminal. Each of the N 10 GbE optical signals transmitted and received via the N optical fibers in the 10 GbE apparatus connecting the 10 N GbE <-> 10 GbE converter and the N 10 GbE wavelength converters, respectively. Are composed of two PCS lane signals grouped based on PCS lane numbers uniquely assigned to 2N PCS (Physical Coding Sublayer) lane signals constituting the 10N GbE optical signal. Of the 10 optical fibers in the 10 GbE device, the 10 Gb By transmitting and receiving through the 10 GbE intra-apparatus optical fiber that is associated with each of the two PCS lane numbers assigned to each optical signal, there is an error in the 10 GbE intra-apparatus optical fiber or the inter-apparatus optical fiber. An optical fiber misconnection detection method, comprising detecting connection.   As the transmission-side PCS processing in the 10N GbE <-> 10GbE converter, each of the two PCS lane signals is specific to each of the N 10 GbE optical signals each composed of two PCS lane signals. One of the 10 GbE intra-apparatus optical fibers associated with the two PCS lane numbers on a one-to-one basis among the N ten-GbE intra-apparatus optical fibers with the assigned PCS lane number The 10 GbE optical signals are respectively transmitted through the N, the N 10 GbE wavelength converters convert the N wavelength divided multiplexed optical signals into the N wavelength-division-multiplexed optical signals, and the N optical fibers are connected via the inter-device optical fibers. 6. The optical fiber misconnection detection method according to claim 5, wherein transmission to an apparatus is performed.   As the reception-side PCS processing in the 10N GbE <-> 10GbE conversion unit, N wavelength division multiplexed optical signals received from the opposite device via the N inter-device optical fibers are converted to obtain the N The PCS lane number assigned to each of the N 10 GbE optical signals transmitted through each 10 GbE intra-apparatus optical fiber, and a pair of each of the N inter-apparatus optical fibers as the transmission side PCS processing If the PCS lane number assigned to each of the N 10 GbE optical signals corresponding to 1 is compared and does not match, there is an error in the 10 GbE intra-apparatus optical fiber or the inter-apparatus optical fiber. The optical fiber misconnection detection method according to claim 6, wherein an alarm indicating that there is a connection is issued to a maintenance person.   The optical fiber misconnection detection method according to claim 5, wherein the 10N GbE optical signal is a 100 GbE optical signal or a 40 GbE optical signal.

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