JP6077630B1 - Frame transmission apparatus and frame transmission method - Google Patents

Abstract

Even if the accommodation information (MSI) of a client signal received using a multiframe is not valid, as many client signals contained in an OTN frame constituting the multiframe as possible are separated from each other. . In response to the determination that the generated MSI is not valid, the value of the region in the generated MSI resulting from the determination that the generated MSI is not valid is stored in the payload regions of a plurality of OTN frames corresponding to the region. The value is rewritten to a value indicating that the client signal is not arranged, and is provided as an MSI used by the separation unit to separate the client signal from the payloads of a plurality of OTN frames constituting the multiframe. [Selection] Figure 7

Description

  The present invention relates to a frame transmission apparatus and a frame transmission method for transmitting a frame storing digital data, and more specifically, to an “optical transport network” (OTN) which is a communication standard used in a backbone communication network. The present invention relates to a frame transmission apparatus and a frame transmission method for transmitting a compliant frame.

  The current backbone communication network is an optical transport network (OTN) recommended by the International Telecommunication Union-Telecommunication Standardization Sector (ITU-T). ) Is widely used. OTN is transparent to accommodate a variety of client signals such as Ethernet (registered trademark) and Synchronous Digital Hierarchy (SDH), monitoring and control systems that are aware of wavelength division multiplexing (WDM) signal management. Defines the bit rate, mapping method, etc. (See Non-Patent Document 1)

  FIG. 1 is a diagram for explaining the frame structure of OTN. Note that the overhead of storing address information and various monitoring signals used when transmitting data is added to the beginning of various frames constituting the OTN frame, but in the following, the overhead is abbreviated as OH and stored in OH. Information and signals transmitted in this manner will be abbreviated as OH information. The OPUk frame 110 includes a payload area 112 in which a client signal 100 such as Ethernet (registered trademark) or SDH is accommodated, and an OPUk (Optical Channel Payload Unit-k) OH area 114 that is OH that provides accommodation information of the client signal. Composed. The ODUk frame 110 is provided with an ODUk (Optical Channel Data Unit-k) OH124, which is an OH that provides (stores) signals for end-to-end path monitoring and performance monitoring. Is done. The ODUk frame 120 provides (stores) signals for maintenance and operation functions necessary for transmission of an optical channel, which is signal transmission between 3R playback (Re-amplification, reshaping, and retiming) points. Transport Unit-k) OH 134 and a code 136 for providing a Forward Error Correction (FEC) function are added to form an OTUk frame 130.

  The OTN has a function of collecting a plurality of OTN frames as one group and transmitting predetermined OH information using the one group of OTN frames. A plurality of OTN frames used for transmission of the predetermined OH information is called “multiframe”, and transmission of predetermined OH information using a plurality of OTN frames constituting the multiframe is called multiframe.

  Hereinafter, the concept of multiframe will be described by taking “Multiplex Structure Identifier” (MSI) transmitted using a plurality of OPUk OHs as an example.

  FIG. 2A is a diagram for explaining the OTN frame structure described in FIG. 1 in more detail. Frame synchronization (FA) OH230 is defined in the first to seventh columns of the first row of the OTN frame, and OTUk OH134 is defined in the following eight to fourteenth rows. ODUk OH124 is defined in the 1st to 14th columns of the 2nd to 4th rows. The OPUk OH 114 is defined in the 15th to 16th columns of the 1st to 4th rows, and the payload 112 is defined in the 17th to 3824th columns of the 1st to 4th rows. An OTUk FEC code 136 is defined in the 3825 to 4080 columns of the first to fourth rows.

  FIG. 2B shows the configuration of the FA OH 230 in the OTN frame. In FA OH, a frame alignment signal (FAS) 232 is defined in the first 6 bytes (corresponding to the first row to the sixth column of the OTN frame), followed by one byte (in the first row, the seventh column). A multi-frame alignment signal (MFAS) 234 is defined. MFAS is equivalent to a counter, and the value of MFAS (MFAS value) is incremented from 0 (“0000 0000” in the bit string) to 255 (“1111 1111”) each time one OTN frame 130 is transmitted. Is granted. When the MFAS value reaches 255, it returns to 0 and is incremented again. A group of OTN frames having an MFAS value of 0 to an OTN frame of No. 255 can constitute a “multiframe”.

  FIG. 2 (c) shows a more detailed configuration of the OPUk OH 114, and particularly shows a configuration of OPU4 OH information transmitted using a plurality of OPU4 OHs. The information of OPU4 OH is OH information transmitted in a multi-frame manner. In each of the 15th and 16th columns of the first to third rows of the OTN frame, a stuff control (Justification Control, JC) byte is defined. Payload Structure Identifier (PSI) is defined in the 15th column of the 4th row of the OTN frame, and OPU Multi-Frame Identifier (OMFI) is defined in the 16th column of the 4th row. Yes. Although only one PSI (one byte, called PSI byte) is defined in one OTN frame 130, PSI bytes transmitted in 256 OTN frames constituting one multiframe are accumulated. OH information (PSI (total 256 bytes)) as shown in the right diagram of FIG. 2C is formed. As described above, PSI transmitted in a multiframe using a multiframe composed of 256 OTN frames is one of OH information. On the other hand, OMFI operating as a counter is defined in the OPUk OH 114 of the OTN frame 130. A value from 0 (“000 0000” in the bit string) to 79 (“100 1111” in the bit string) is incremented and added in the order of transmission of the OTN frame using the lower 7 bits of 1 byte constituting the OMFI 246. That is, OMFI forms one multiframe with 80 OTN frames.

  Among the information of OPU4 OH, 80 bytes obtained by accumulating the PSI bytes of the OTN frames whose MFAS 234 values are 2 to 81 constitute a multiplex structure extension (MSI) 244. The MSI stores information indicating how client signals are accommodated in the OPUk payload 112. More specifically, each byte of the MSI indicates whether the tributor slot (TS) is placed in the OPUk payload 112, and if a TS is placed, the TS tributary port number (TS destination (TS The number of the client accommodated in TS is a slot to which a tributary unit to which a client signal is mapped is further mapped.

  As described above, OTN provides a function for accommodating a variety of client signals and transmitting the network. However, client signal accommodation information is transmitted using an 80-byte MSI obtained from one multiframe. Shared between devices. The frame transmission apparatus on the transmission side forms PSI, which is the 256-byte OH information (OPU4 OH information) shown in the right diagram of FIG. 2C, from the 80-byte MSI provided by the control unit. The first byte of the OH information in the PSI byte of the OTN frame in which the MFAS value in OH is set to 0, the second byte of the OH information in the PSI byte of the OTN frame in which the MFAS value is set to 1, ... The 256th byte of the OH information is sequentially added to the PSI byte of the OTN frame in which the value of MFAS is set to 255.

  On the other hand, the frame transmission apparatus on the receiving side, based on each OH of the received OTN frame, includes PSI (information of OPU4 OH, which is OH information (right of FIG. 2 (c))) consisting of 256 bytes and 80 included therein. Form the MSI of the byte and separate the client signal from the OTN frame based on the formed MSI.

  A method for accommodating / separating the client signal from the OPU 4 will be described with reference to FIG. This process is performed by the OTN framer of the frame transmission apparatus. The client signal 100 is accommodated asynchronously in the optical channel data tributary unit 4.ts (ODTU4.ts) with stuff overhead (not shown) added. Up to 80 ODTU4.ts signals (102-1 to 102-80) are accommodated in each of the 80 tributary slots (TS1 to 80) allocated to the payload 112 of the OPU4 frame 110. The OPU4 frame 110 is accommodated in the payload of the ODU4 frame 120 with an OPU4 overhead 124 added.

  FIG. 4 shows the arrangement of TSs in the OPU4 frame. That is, 80 TSs are byte-interleaved and accommodated in an area of 17 to 3816 columns in each row in a multi-frame (4 × 80 = 320 rows) composed of 80 OTN frames. In FIG. 4, the numbers given to each byte in the 17-3816 column area represent the TS identification numbers (1-80). Note that the multiframe composed of the 80 OTN frames is defined by the OMFI described above.

  FIG. 5 shows a specific configuration of the MSI in the OPU4 frame. For example, the OTN framer of the frame transmission device accommodates the client signal in the OTN frame based on the MSI provided from the control unit, forms the PSI that is OH information (OPU4 OH information), and each OTN frame Set a value in the PSI byte. The first line of the MSI shown in FIG. 5 is a PSI byte (byte in the fourth row and the 15th column) in the OTN frame in which the MFAS value is set to 2, and represents client signal accommodation information in the TS1. Similarly, the second line of MSI is the PSI byte of the OTN frame in which the MFAS value is set to 3, and the 80th line is the PSI byte of the OTN frame in which the MFAS value is set to 81. Each byte constituting the MSI 244 represents client signal accommodation information in the TS described at the right end of FIG. In the first 1 bit of each byte of the MSI, “Occupation” indicating whether or not a client signal is arranged in the corresponding TS is set. When the value of Occupation is 1, the client signal is allocated, and when the value is 0, the client signal is not allocated. The 2nd to 8th bits of each byte of the MSI represent a tributary port number and indicate the port number of ODTU4.ts transferred by the corresponding TS. The tributary port number is the number of the client accommodated in each TS. For example, a client signal having a tributary port number of PSI [2] is accommodated in TS1, and a client signal having a tributary port number of PSI [3] is accommodated in TS2.

  When the value of the first bit (Occupation) of each byte of MSI is “0”, the 2nd to 8th bits (bits for which the tributary port number is set) of the byte are also set to all “0”. Is done. That is, when a client signal is not allocated to a certain TS, “0” is set in the corresponding MSI.

  On the other hand, the receiving-side frame transmission apparatus generates a PSI including an MSI from the received OTN frame, and extracts (separates) each client signal accommodated in the TS according to the MSI tributary port number.

In addition, ITU-T defines a virtual concatenation technique in which one high-speed OTN frame accommodating a client signal is divided and transmitted using a plurality of low-speed lanes in OTN. (See Non-Patent Document 1)
FIG. 6 is a diagram for explaining the configuration of an OPUk-Xv frame transmitted using a virtual concatenation technique defined by OTN recommended by ITU-T. The client signal is stored in the payload area of the OPUk-Xv frame shown in the upper part of FIG. 6 by a framer multiplexer included in the frame transmission apparatus on the transmission side. Further, the OPUk-Xv frame output from the multiplexer is input to the divider provided in the framer of the transmission side frame transmission apparatus, and divides the OPUk-Xv frame into X OPUk frames shown in the lower part of FIG. . For example, when X = 3, the divider separates the OPUk-Xv frame for each column, combines the 3n + 1 column (n = 0, 1, 2,...), And combines the first OPUk frame (OPUk # 1) form. Similarly, the 3n + 2 column is combined to form the second OPUk frame (OPUk # 2), and the 3n + 3 column is combined to form the third OPUk frame (OPUk # 3). The OPUk frame divided into X pieces is added with an ODUk OH to form an ODUk frame, and then an OTUk OH is added to form an OTUk frame. Each OTUk frame is converted into an optical signal having a different wavelength, and is multiplexed, for example, and transmitted to a frame transmission apparatus on the receiving side.

  As shown in FIG. 6, the OH of each OPUk # x frame (x = 1, 2,...) Divided from the OPUk-Xv frame includes the first column and the fourth row (if the OTUk frame is used, the 15th column and the fourth row). PSI byte is defined in 1 byte (equivalent to eye). MSI is included in the PSI obtained by accumulating one PSI byte for one multiframe. The MSI of each OPUk frame represents the accommodation information of the client signal contained in its own payload. On the receiving side, for each OPUk frame #X (X = 1, 2,...) Transmitted after being divided, the PSI bytes of one multi-frame OPUk frame #X are accumulated to form a PSI including MSI. Each client signal contained in the TS is extracted (separated) according to the formed MSI tributary port number.

International Telecommunication Union, “Interfaces for the optical transport network,” Recommendation ITU-T G.709 / Y.1331, February 2012

  As shown in FIG. 2A, an FEC code is assigned to the OTN frame. The OTN framer of the frame transmission apparatus can correct the bit error using the FEC code even if a bit error has occurred in the received OTN frame.

  However, even such an OTN FEC function is not universal, and if the bit error exceeds a predetermined allowable value, the OTN framer may not be able to correct the bit error included in the OTN frame. Assume that a bit error remains in the PSI byte in the OPUk OH of one OTN frame. In this case, since the 80-byte MSI obtained from one multiframe is not correct information, the transmission apparatus can correctly separate the client signal from all of the OTN frames for one multiframe including the bit error. Can not.

  As described above, the OTN has a function of making a plurality of OTN frames into one group and transmitting the predetermined OH information by making the OTN frame (multiframe) into a single frame using the one group of OTN frames. When even one bit error remains in the accommodation information (MSI) of the client signal that is used and transmitted, the receiving side frame transmission apparatus can correctly separate the client signal from all of the multi-frame OTN frames. There was a problem that it was not possible.

  The present invention has been made in view of such a problem, and an object of the present invention is to provide a multi-frame even if the accommodation information (MSI) of a client signal received using multi-frame is not valid. It is an object of the present invention to provide a frame transmission apparatus and method for relieving (separating) as many client signals as possible from an OTN frame constituting a frame.

  In order to achieve such an object, the frame transmission device determines the validity of the MSI formed from the received OTN frame, and if it is determined to be invalid, the MSI resulting from the determination that it is not valid. Assuming that the client signal is not arranged in the OTN frame corresponding to this area, the MSI area is rewritten, and the client signal is separated using the rewritten MSI.

  One embodiment of the present invention is a frame transmission device that receives a frame of an optical transmission network (OTN). The frame transmission device sequentially buffers at least a part of the overhead of a plurality of OTN frames constituting the received multiframe and the overhead of the plurality of OTN frames buffered sequentially. Means for generating client signal accommodation information for accommodating client signals in the payload, and a client for determining the validity of the generated client signal accommodation information and separating the client signals from the payloads of a plurality of OTN frames constituting a multiframe Means for providing signal accommodation information, and means for separating the client signal from the payloads of a plurality of OTN frames constituting the multiframe based on the provided client signal accommodation information. In response to the determination, the frame transmission apparatus uses the value of the region including at least the region in the generated client signal accommodation information resulting from the determination of invalidity as the payload of the plurality of OTN frames corresponding to the region. The generated client signal accommodation information that has been rewritten to a value indicating that no client signal is allocated to the client is provided as client signal accommodation information for separating client signals from the payloads of a plurality of OTN frames that constitute the multiframe. To do.

  In one embodiment, the frame transmission apparatus further comprises means for storing at least one previously generated client signal accommodation information. If the comparison result between the previously generated at least one client signal accommodation information and the generated client signal accommodation information does not match, it is determined that the generated client signal accommodation information is not valid.

  In one embodiment, in the frame transmission apparatus, the frame of the optical transmission network (OTN) is divided into a plurality of frames and received in parallel. The frame transmission apparatus further includes means for adjusting synchronization between a plurality of divided and parallel received frames and providing synchronization information indicating whether the synchronization adjustment is successful or unsuccessful. If the synchronization information indicates that the synchronization adjustment has failed, it is determined that the generated client signal accommodation information is not valid.

  One embodiment of the present invention is a frame transmission method for receiving an OTN frame.

  As described above, according to the present invention, as many clients as possible from the OTN frame constituting the multiframe can be obtained even when the accommodation information (MSI) of the client signal received using the multiframe is not valid. A frame transmission apparatus and method for relieving (separating) a signal can be provided.

It is a figure explaining the frame structure of OTN. (A) is a diagram for explaining the OTN frame structure in more detail, (b) is a diagram showing the configuration of FA OH in the OTN frame, and (c) is an OPU4 OH transmitted using a plurality of OPU4 OHs. It is a figure which shows the structure of this information. It is a figure for demonstrating the accommodation / separation method to the OPU4 of a client signal. It is a figure which shows arrangement | positioning of the tributary slot (TS) in an OPU4 frame. It is a figure which shows the specific structure of MSI in an OPU4 frame. It is a figure which shows the structure of an OPUk-Xv frame. (A) is a figure explaining the structure of the frame transmission system which concerns on one Embodiment of this invention, (b) is a figure explaining the structure of the OTN framer which concerns on one Embodiment of this invention. FIG. 6 illustrates a multiple structure extension (MSI) provided for client signal separation processing in accordance with one embodiment of the present invention. (A) is a figure explaining the structure of the frame transmission system which concerns on one Embodiment of this invention, (b) is a figure explaining the structure of the OTN framer which concerns on one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The frame transmission apparatus according to the present embodiment is an apparatus that transmits an OTN frame (a frame specified (defined) by the OTN standard). When a frame transmission apparatus that transmits an OTN frame forms an OTN frame that constitutes a multiframe, client signal accommodation information (for example, multiple structure extension) about the accommodation of the client signal in the payload of the OTN frame that constitutes the multiframe Child (MSI)) is transmitted in a multi-frame form.

  On the other hand, when a frame transmission device that receives an optical transmission network (OTN) frame separates a client signal from an OTN frame that constitutes a multiframe, the frame transmission apparatus receives a multiframe by a plurality of OTN frames that constitute the multiframe. The client signal accommodation information is used to separate the client signal from the payload of the OTN frame constituting the multiframe.

(First embodiment)
FIG. 7A is a diagram illustrating the configuration of a frame transmission system including the frame transmission apparatus according to the present embodiment. The frame transmission system 400 in FIG. 7A includes a plurality of frame transmission apparatuses A 420, a plurality of frame transmission apparatuses B 460, and a network 440 that connects these frame transmission apparatuses. Normally, a frame transmission apparatus has both a function for transmitting and receiving an OTN frame, but for the sake of simplicity of explanation, the frame transmission apparatus A420 has a configuration having only a transmission function, and the frame transmission apparatus B460 has a reception function. A description will be given assuming that the configuration has only functions.

  The transmission-side frame transmission apparatus A 420 includes an OTN framer 422 that accommodates a client signal in the OTN frame having the configuration shown in FIGS. 1 and 3, and an optical transmission that converts the OTN frame of the electrical signal output from the OTN framer into an optical signal. Device (TX) 424. In addition, the frame transmission apparatus A 420 normally includes an optical wavelength division multiplexing (WDM) apparatus 426 that wavelength-multiplexes a set of a plurality of OTN framers 422 and an optical transmitter 424 and optical signals having different wavelengths output from the plurality of optical transmitters. With. The wavelength-multiplexed optical signal is transmitted to the network 440.

  The reception-side frame transmission apparatus B 460 includes an optical receiver (RX) 464 that converts an optical signal received via the network 440 into an OTN frame of an electrical signal, and an OTN framer 462 that separates a client signal from the OTN frame. . The frame transmission apparatus B 460 normally includes a set of a plurality of OTN framers and optical receivers, and an optical wavelength multiplexing apparatus (WDM) 466. Since the optical signal received via the network 440 is wavelength multiplexed, it is separated into an optical signal of a single wavelength by an optical wavelength multiplexing (WDM) device 466. Each optical signal is converted into an OTN frame of an electrical signal by the optical receiver 464, and then the client signal is separated by the OTN framer 462.

  FIG. 7B is a diagram illustrating the configuration of the OTN framer according to the present embodiment. Unlike the description of FIG. 7A, in a universal implementation, the OTN framer has both a client signal accommodation function and a separation function. Therefore, FIG. 7B shows the configuration of the OTN framer (422, 462) equipped with both the accommodation function and the separation function. The OTN framer (422, 462) receives the OTN frame of the electrical signal output from the optical receiver 464, receives the OTN frame stored in the reception buffer, and receives the OTN frame stored in the reception buffer. And a separator 488 that separates the client signal contained in the OPUk payload, receives the client signal, stores it in the OPUk payload, forms a OTN frame by adding a predetermined OH, and outputs it to the optical transmitter 424. A multiplexer 484 and a control unit 482 that provides the MSI to the multiplexer 484 for the accommodation process and determines the validity of the MSI for the separation process and provides the MSI to the separator 488. The reception buffer 486 may be an OH reception buffer that stores only the OH (OPUk-OH, ODUk-OH, OTUk-OH, FAOH) of the received OTN frame. When the reception buffer 486 stores only the OH of the received OTN frame, the received OTN frame is supplied to the reception buffer 486 and the separator 488 in parallel.

(Containment processing)
The control unit 482 of the OTN framer forms a 256-byte PSI including the 80-byte MSI that is the accommodation information of the client signal, and provides it to the multiplexer 484 (step A1).

  Next, the OTN framer multiplexer 484 adds the stuff overhead to the received client signal according to the MSI provided from the control unit 482 and adds the stuff overhead to the optical channel data tributary unit 4. ts (ODTU4.ts) and in the tributary slot (TS), and further in the OPUk payload 112, OPUk OH114, ODUk OH124, OTUk OH134, OTUk FEC136 and FA OH230 are given to the OPUk payload, An OTN frame 130 is formed (step A2). Here, the PSI byte 242 of the OPUk OH 114 of the OTN frame 130 is provided with 1-byte information corresponding to the MFAS value of the 256-byte PSI including the 80-byte MSI provided from the control unit 482. Is done.

  Thereafter, the OTN framer multiplexer 484 outputs the formed OTN frame to the optical transmitter 424 (step A3). As described above, in the conventional accommodation processing, client signal accommodation information regarding the accommodation of the client signal in the payload of the OTN frame is multiplexed using a plurality of 256 OTN frames in the multiframe having the OTN frame as a constituent element. Frame and transmit.

(Separation process)
In the separation processing of this embodiment, the reception buffer 486 of the OTN framer 462 of the frame transmission device B 460 on the reception side sequentially stores the received OTN frame (OH), and the control unit 482 of the OTN framer stores the reception buffer 486 in the reception buffer 486. The MFAS value and the PSI byte are received from the stored OTN frame, and a 256-byte PSI including the MSI is formed (step B1).

  Based on the MFAS value of the received OTN frame, the control unit 482 of the OTN framer 462 confirms that one frame (that is, 256) of OTN frames (of OH) is stored in the reception buffer 486 based on the MFAS value of the received OTN frame. The validity of MSI is determined (step B2). If it is determined that the MSI is valid, the MSI is provided to the separator 488. If it is determined that the MSI is not valid, the region in the MSI resulting from the determination that the MSI is not valid is specified, set to a predetermined value, and provided to the separator 488. For example, if it is confirmed that the formed MSI is not valid due to the inclusion of a bit error or the like, as shown in FIG. 7B, the byte including the bit error in the MSI is specified and the corresponding byte is supported. Assuming that the client signal is not arranged in the TS to be set, the byte is set to 0 (rewrites “0000 0000” in the bit string) and provided to the separator 488.

  The separator 488 of the OTN framer 462 separates and outputs the client signal from the OTN frame included in the received multiframe based on the MSI provided from the control unit 482 (step B3).

  Note that the validity of MSI in step B2 is determined by, for example, comparing the previously received MSI (MSI formed from a previously received multiframe) with the latest MSI, and determining whether there is a mismatch bit between the two. The validity should be determined. That is, the control unit 482 stores at least one MSI received (generated) in an internal or external storage unit (not shown), and between the previously received MSI and the latest MSI. If there is a mismatch bit, it may be determined that the bit is incorrect. Here, the MSI received before being compared with the latest MSI may be a plurality of previously received MSIs (MSIs having the same value for each constituent value). It is rare that the MSI values are changed and restored in a short time. Therefore, the greater the number of standard MSIs, the more reliable the validation.

  FIG. 8 illustrates a case where a bit error remains in the byte (PSI [4]) in the third row of the formed MSI. By comparison with the MSI formed from the previously received multiframe, the byte in the third row of the latest MSI is identified as the area resulting from the determination that the latest MSI formed is not valid, and the value of this byte is Set to 0 (PSI [4] is set to 0000 0000). As a result, it is processed that the client signal is not accommodated in TS3 interleaved in the OTN frame in the multiframe corresponding to the byte in the third row.

  In step B2 of the separation process described above, “if the control unit 482 determines that the MSI is not valid, it identifies an area in the MSI resulting from the determination that the MSI is not valid, and sets the area to 0 (rewrite). I) provide MSI to separator 488. " However, the present invention is not limited to such an implementation. For example, the control unit 482 specifies “the region in the MSI resulting from the determination that the MSI is not valid, The region may be masked with 0 ”. In this case, the separator 488 of the OTN framer 462 does not “receive MSI from the control unit 482” in step B3, but “refers to the MSI masked by the control unit 482” to generate the client signal. May be separated.

  As described above, according to the frame transmission apparatus according to the present embodiment, even if the received (formed) MSI is not valid, the client signal separation processing by the MSI is not stopped. The client signal included in the TS other than the TS corresponding to the byte in which the bit error exists can be received correctly. That is, even if there is a bit error in MSI, many client signals can be relieved.

(Second Embodiment)
The present embodiment is an embodiment in which the present invention is applied to the virtual concatenation technique described with reference to FIG.

  FIG. 9A is a diagram illustrating the configuration of a frame transmission system including the frame transmission apparatus according to the present embodiment. The frame transmission system 500 in FIG. 9A includes a plurality of frame transmission apparatuses A520, a plurality of frame transmission apparatuses B560, and a network 540 that connects these frame transmission apparatuses. Frame transmission apparatuses A and B are frame transmission apparatuses that implement virtual concatenation technology. Normally, the frame transmission apparatus has both a function for transmitting and receiving an OTN frame, but for the sake of simplicity of explanation, the frame transmission apparatus A520 has a configuration having only a transmission function, and the frame transmission apparatus B560 has a reception function. A description will be given assuming that the configuration has only functions.

  The transmission-side frame transmission apparatus A520 accommodates the client signal in the OPUk-Xv frame having the configuration shown in the upper part of FIG. 6, and the OPUk # x frame (x = 1, 2,... Having the configuration shown in the lower part of FIG. OTN framer 522 that outputs an OTUk frame (OTN frame) of an electric signal obtained by adding ODUk OH and OTUk OH to each of OPUk # x frames (x = 1, 2,...), And OTN framer 522 And an optical transmitter (TX) 524 that converts the OTN frame of the output electrical signal into an optical signal. And an optical wavelength multiplexing (WDM) device 526 that wavelength-multiplexes optical signals having different wavelengths output from the plurality of optical transmitters 524. The wavelength-multiplexed optical signal is transmitted to the network 540.

  The receiving-side frame transmission apparatus B 560 includes an optical wavelength division multiplexing (WDM) apparatus 566 that separates a wavelength multiplexed optical signal received via the network 540 into an optical signal having a single wavelength, and a single received via the network 540. An optical receiver (RX) 564 that converts an optical signal with a wavelength of 0 into an OTN frame (OTUk frame) of an electrical signal, and an OPUk # x frame (x = 1, 2,…) is extracted from the OTUk frame, and OPUk-Xv An OTN framer 562 for restoring the frame and separating the client signal.

  FIG. 9B is a diagram illustrating the configuration of the OTN framer according to the present embodiment. Note that, unlike the description of FIG. 9A, in a universal implementation, the OTN framer has both a client signal accommodation function and a separation function. Therefore, FIG. 9B shows the configuration of the OTN framer (522, 562) equipped with both the accommodation function and the separation function.

  An OTN framer (522, 562) receives an OTN frame including an OPUk frame of an electrical signal from each of the optical receivers 564, and absorbs a phase difference between the OPUk frames to restore an OPUk-Xv frame. Receive buffer 586 that stores the OPUk-Xv frame, a separator 588 that receives the OPUk-Xv frame stored in the receive buffer 586 and separates the client signal, and receives the client signal into the payload of the OPUk-Xv frame A multiplexer 584 that stores and outputs a OPUk-Xv frame with a predetermined OH, and divides the OPUk-Xv frame into X pieces to generate X OTUk frames (OTN frames, including OPUk frames). .) To the optical transmitter 524, the MSI is provided to the multiplexer 584 for the accommodation process, and the validity of the MSI for the separation process is determined and provided to the separator 588. And a control unit 582. The reception buffer 586 may be an OH reception buffer that stores only the received OPUk-Xv frame OH.

  The divider 592 receives the OPUk-Xv frame (upper part of FIG. 6) containing the client signal, divides it into OPUk # x frames (x = 1, 2,...) (Lower part of FIG. 6), and the OPUk # x frame. An OTUk frame (OTN frame) of an electric signal with ODUk OH and OTUk OH added to each of (x = 1, 2,...) Is output. Each OTN frame is supplied to a corresponding optical transmitter 524, converted into an optical signal having a different wavelength, and wavelength-multiplexed with other optical signals and transmitted. As described with reference to FIG. 6, the PSI byte is defined in 1 byte of the first column and the fourth row of each OPUk # x frame (corresponding to the 15th column and the fourth row in the case of the OTUk frame). MSI is included in the PSI obtained by accumulating one PSI byte for one multiframe. The MSI of each OPUk # x frame represents the accommodation information of the client signal contained in its own payload.

  The restorer 594 includes a buffer (not shown) for adjusting the frame synchronization by absorbing the phase difference between the plurality of OPUk # x frames (x = 1, 2,...), And a plurality of OPUk having adjusted frame synchronization. Restore one OPUk-Xv frame (upper part of Fig. 6) from the #x frame. The restorer 594 supplies frame synchronization information (synchronization information). The synchronization information indicates whether the adjustment of the synchronization of the plurality of OPUk # x frames in the restorer 594 has succeeded or failed (so-called out of synchronization has occurred). The synchronization information may be configured to explicitly or implicitly indicate that the synchronization adjustment has failed, to indicate only that it has failed, or to indicate only that it has succeeded. The synchronization information includes information that enables identification of an OPUk # x frame caused by a synchronization adjustment failure among a plurality of OPUk # x frames.

  The reception buffer 586 stores the restored OPUk-Xv frame. The reception buffer 586 may be an OH reception buffer that stores only the received OPUk-Xv frame OH.

(Containment processing)
The multiplexer 584 of the OTN framer 522 of the transmitting side frame transmission apparatus A520 receives the client signal, stores it in the payload of the OPUk-Xv frame (upper part of FIG. 6), adds a predetermined OH, and sends the OPUk-Xv frame. Output. The divider 592 of the OTN framer 522 receives the OPUk-Xv frame containing the client signal (upper part of FIG. 6), divides it into OPUk # x frames (x = 1, 2,...) (Lower part of FIG. 6), An OTUk frame (OTN frame) of an electric signal with ODUk OH and OTUk OH added to each of OPUk # x frames (x = 1, 2,...) Is output. At this time, a PSI byte is defined in one byte of the first column and the fourth row of each OPUk # x frame (corresponding to the 15th column and the fourth row in the case of the OTUk frame), and the PSI of the OPUk # x frame is converted into multiframe To be transmitted.

  The optical transmitters 524 of the transmission-side frame transmission apparatus A 520 each convert the OPUk # x frame into optical signals having different wavelengths, and the optical wavelength multiplexing apparatus 526 performs wavelength multiplexing together with other optical signals.

(Separation process)
In the separation processing of the present embodiment, the restoring device 594 of the OTN framer 562 of the receiving-side frame transmission device B 560 receives the OPUk # x frames (x = 1, 2,...) From the optical receivers 564-1,. ), And adjust (synchronize) the plurality of OPUk # x frames so that there is no phase difference between them to restore one OPUk-Xv frame (step C0). The restored OPUk-Xv frames are sequentially supplied to the reception buffer 586. For example, synchronization is attempted using FA OH of each OPUk # x frame (OTN frame).

  The reception buffer 586 of the OTN framer 562 of the frame transmission device B 560 on the reception side sequentially stores the received OPUk-Xv frames (OH), and the control unit 582 of the OTN framer stores the OPUk-Xv stored in the reception buffer 586. All PSI bytes corresponding to X OPUk frames are sequentially received from the frame, and one multiframe is accumulated to form a PSI including MSI (step C1).

  The control unit 582 of the OTN framer 562 determines the validity of the latest MSI formed (step C2). If it is determined that the MSI is valid, the MSI is provided to the separator 588. If it is determined that the MSI is not valid, the region in the MSI resulting from the determination that the MSI is not valid is identified, and a part of the X OPUk frames (the OPUk that included the region) is supported. The MSI to be set is set to a predetermined value and provided to the separator 588. When it is confirmed that the client signal is not valid, as shown in FIG. 9B, it is assumed that the client signal is not arranged in the OPUk frame including the bit error among the plurality of latest MSIs. All bytes of the MSI corresponding to the OPUk frame are set to 0 (rewritten as “0000 0000” in the bit string) and provided to the separator 588.

  The separator 588 of the OTN framer 562 separates and outputs the client signal from the OTN frame included in the received multiframe based on the MSI provided from the control unit 582 (step C3).

  Note that the validity of the MSI in step C2 may be determined based on the synchronization information provided by the decompressor 594. That is, when the synchronization information indicates that frame synchronization has failed (out-of-synchronization state), the control unit 582 causes the OPUk (corresponding OTN frame) in which this out-of-synchronization has occurred to have a predetermined ratio or more bits. What is necessary is just to determine that MSI corresponding to the said OPUk is not valid as an error is included.

  As in the first embodiment, the control unit 582 of the OTN framer 562 may “mask the MSI corresponding to the OPUk frame including the bit error with 0”. In this case, the separator 588 of the OTN framer 562 may “separate the client signal by referring to the MSI masked by the control unit 582”.

  As described above, according to the frame transmission apparatus according to the present embodiment, even if the received (formed) MSI is not valid, the client signal separation processing by the MSI is not stopped. Thus, the client signal included in the OPUk frame other than the OPUk frame in which the bit error exists (corresponding to the OTN frame) can be received correctly. That is, even if there is a bit error in MSI, many client signals can be relieved.

100 Client signal 102 ODTUk.ts
110 OPUk frame 112 OPUk payload 114 OPUk overhead 120 ODUk frame 124 ODUk overhead 130 OTUk frame 134 OTUk overhead 136 OTUk FEC
230 Frame synchronization (FA) overhead 232 Frame synchronization signal (FAS)
234 Multi-frame synchronization signal (MFAS)
242 Payload structure identifier (PSI)
244 Multiple Structure Extension (MSI)
246 OPU Multiframe Identifier (OMFI)
400,500 frame transmission system 420,460,520,560 frame transmission device 422,462,522,562 OTN framer 440,540 network 424,524 optical transmitter 426,466,526,566 optical wavelength multiplexing device 464,564 light Receiver 482, 582 Control unit 484, 584 Multiplexer 486, 586 Receive buffer 488, 588 Separator 592 Divider 594 Restorer

Claims (6)

A frame transmission device for receiving an optical transmission network (OTN) frame,
Means for sequentially buffering at least part of the overhead of a plurality of OTN frames constituting the received multiframe;
Means for generating client signal accommodation information for accommodation of client signals in payloads of a plurality of OTN frames constituting a multi-frame from the overhead of a plurality of OTN frames buffered sequentially;
Means for determining the validity of the generated client signal accommodation information and providing client signal accommodation information for separating client signals from the payloads of a plurality of OTN frames constituting a multiframe;
Means for separating a client signal from payloads of a plurality of OTN frames constituting a multi-frame based on provided client signal accommodation information;
In response to the determination that the generated client signal accommodation information is not valid, a value of an area including at least an area in the generated client signal accommodation information resulting from the determination that the client signal accommodation information is not valid corresponds to the area. For separating the client signal from the payloads of the plurality of OTN frames constituting the multiframe, the generated client signal accommodation information rewritten to a value indicating that no client signal is arranged in the payloads of the plurality of OTN frames. A frame transmission device provided as client signal accommodation information. Means for storing at least one previously generated client signal accommodation information;
The generated client signal accommodation information is determined to be invalid if the comparison result between the previously generated at least one client signal accommodation information and the generated client signal accommodation information does not match. The frame transmission device described. The frame of the optical transmission network (OTN) is divided into a plurality of frames and received in parallel.
Means for adjusting synchronization between a plurality of frames that are divided and received in parallel, and providing synchronization information indicating whether the synchronization adjustment has succeeded or failed;
The frame transmission device according to claim 1, wherein when the synchronization information indicates that the synchronization adjustment has failed, the generated client signal accommodation information is determined to be invalid. A frame transmission method for receiving an optical transmission network (OTN) frame,
Sequentially buffering at least some of the overhead of multiple OTN frames that comprise the received multiframe;
Generating client signal accommodation information about the accommodation of client signals in the payloads of a plurality of OTN frames constituting a multi-frame from the overhead of a plurality of OTN frames buffered sequentially,
Determining the validity of the generated client signal accommodation information, providing client signal accommodation information for separating client signals from the payloads of a plurality of OTN frames constituting a multiframe;
Separating the client signal from the payloads of a plurality of OTN frames constituting the multiframe based on the provided client signal accommodation information, the method comprising:
In response to the determination that the generated client signal accommodation information is not valid, a value of an area including at least an area in the generated client signal accommodation information resulting from the determination that the client signal accommodation information is not valid corresponds to the area. Rewriting to a value indicating that no client signal is arranged in the payload of a plurality of OTN frames, and the generated client signal accommodation information in which the value of the area is rewritten includes a plurality of OTNs constituting the multiframe. A frame transmission method provided as client signal accommodation information for separating a client signal from a payload of a frame. The method further comprises storing at least one previously generated client signal accommodation information;
Determining the validity of the generated client signal accommodation information includes comparing the previously generated at least one client signal accommodation information with the generated client signal accommodation information, and the results of the comparison match The frame transmission method according to claim 4, further comprising: determining that the generated client signal accommodation information is not valid if not. The optical transmission network (OTN) frame is divided into a plurality of frames and received in parallel, and the method includes:
Further comprising adjusting synchronization between a plurality of frames that are divided and received in parallel, and providing synchronization information indicating whether the synchronization adjustment is successful or unsuccessful;
Determining the validity of the generated client signal accommodation information includes determining that the generated client signal accommodation information is not valid when the synchronization information indicates that the synchronization adjustment has failed. The frame transmission method according to claim 4.