WO2017154135A1

WO2017154135A1 - Transmission system

Info

Publication number: WO2017154135A1
Application number: PCT/JP2016/057377
Authority: WO
Inventors: 秀徳清水; 聖史斧原
Original assignee: 三菱電機株式会社
Priority date: 2016-03-09
Filing date: 2016-03-09
Publication date: 2017-09-14
Also published as: JP6501968B2; JPWO2017154135A1

Abstract

A transponder (130) is provided with: a signal conversion unit (132) that generates an OTU frame in which specific-format data transmitted at a first transmission rate is stored; a signal processing unit (133) that generates m division frames by removing FEC data from the OTU frame, dividing the OTU frame in a column direction into predetermined m storage frames, and adding, to a region from which the FEC data have been removed, skew information indicating arrangement positions of the respective m storage frames in the OTU frame; and a communication interface unit (134) that transmits each of the m division frames at a second transmission rate. A transponder (140) is provided with: a communication interface unit (141) that receives each of the m division frames; a signal processing unit (143) that generates a frame by combining each of the m division frames with reference to the skew information; and a signal conversion unit (144) that extracts the specific-format data from the generated frame.

Description

Transmission system

The present invention relates to a transmission system, and more particularly to a transmission system including a plurality of transponders that perform transmission using an optical fiber.

Conventionally, transmission systems using transponders have been used. In such a transmission system, when transmitting a signal from a customer transmission apparatus, a network path is constructed in which transponders are connected in multiple stages between a plurality of stations.

Since the transponders installed in the station are for communication within the station, the communication modules of the transponder include XFP (10 Gigabit Small Form-Factor Pluggable), SFP + (Small Form-Factor Pluggable Plus), and CFP (-100 Gfg-Fulg). ) Etc. are used. The types of signals between the customer transmission device and the transponder include SDH (Synchronous Digital Hierarchy), Ethernet (registered trademark), and OTN (Optical Transport Network), etc., and the transmission rates are 10 Gbps, 40 Gbps, 100 Gbps, and the like. Various types of rates are mixed.

When constructing a network path, the transmission rate of the transponder is generally matched to the transmission rate of the customer transmission device. If the transmission rate of the signal output from the customer transmission device to the transponder is changed during operation of the network path, the change may cause a problem in the connection between the transponders.
Even in such a case, the transponder in the station can cope with the change in the transmission rate by only exchanging the transponder connected to the customer transmission apparatus by dividing the signal into a plurality of lanes and transmitting the signal. There is a case.

For example, when the signal from the customer transmission device is changed from a signal of 100 Gbps to a signal of 10 Gbps, the transponder at the termination point connected to the customer transmission device is changed to a transponder corresponding to the client interface of 10 Gbps. This transponder can cope with such a change by using OTU4 as a client interface. OTU4 is an ITU-T (International Telecommunications Union Telecommunication Standardization Sector) recommendation G. 709, 10 signals of 10 Gbps can be accommodated, and 10 Gbps signals can be transmitted transparently.

Here, as a technique for transmitting a signal by dividing it into a plurality of lanes, G. There is a technology that uses OTL 4.10 defined in 709 Annex C. The OTL 4.10 divides and transmits the 10G signal in units so that the frame alignment signal (FAS) for detecting frame synchronization is at the head of the OTU4 signal. The system described in Patent Document 1 inserts data that can identify a lane into the FAS area, and divides the signal into arbitrary lanes.

JP 2011-223454 A

However, even in OTU4, when a path operated by a client interface supporting 10 Gbps is changed to a client interface supporting 100 Gbps, in order to transmit a 100 Gbps signal transparently, all transponders on the path are set to 100 Gbps. It is necessary to change to a transponder for the client.

Also, if the operating network path is changed to a client interface with a different rate from the operation, G. When the OTL defined in 709 Annex C is used, a circuit having a huge memory is required to receive the 20 OTU frame and correct the delay amount. Also in the system described in Patent Document 1, a circuit having a huge memory is required to synthesize signals having different rates.

Therefore, an object of the present invention is to enable a signal to be divided and transmitted using a plurality of optical fibers with a relatively small memory and corresponding to a change in transmission rate.

A transmission system according to a first aspect of the present invention includes a first transponder that receives data of a specific format transmitted at a first transmission rate, and m (m is an integer of 2 or more) optical fibers. A transmission system including a second transponder connected to the first transponder, wherein the first transponder receives a specific type of data transmitted at the first transmission rate. 1 receiving unit, a first signal converting unit that generates an OTU frame storing data of a specific format received by the first receiving unit, and an OTU frame generated by the first signal converting unit The FEC data is deleted from the data, and is divided into m storage frames determined in advance in the column direction, and the FEC data is deleted in each of the m storage frames. The first signal processing unit that generates m divided frames by adding skew information indicating the arrangement position of each of the m storage frames in the OTU frame, and the first signal processing unit. A first transmission unit that transmits each of the m divided frames at a second transmission rate from each of the m optical fibers to the second transponder, and the second transponder includes: A second receiving unit that receives each of the m divided frames transmitted from the first transmitting unit from each of the m optical fibers, and the m divided frames received by the second receiving unit. A second signal processing unit that generates a frame by combining each of the m divided frames received by the second receiving unit with reference to skew information included in each of the frames; Signal processing A second signal conversion unit that extracts the data in the specific format from the frame generated in step (b), and transmits the data in the specific format extracted by the second signal conversion unit at the first transmission rate. A second transmission unit.

The transmission system according to the second aspect of the present invention includes a first transponder that receives data of a specific format transmitted at a first transmission rate, and m (m is an integer of 2 or more) optical fibers. A transmission system including a second transponder connected to the first transponder, wherein the first transponder receives a specific type of data transmitted at the first transmission rate. 1 receiving unit, a first signal converting unit that generates an OTU frame storing data of a specific format received by the first receiving unit, and an OTU frame generated by the first signal converting unit Are divided into predetermined m storage frames in the column direction, and each of the m storage frames in the OTU frame is arranged at the end of each of the m storage frames. By adding skew information indicating the position, a first signal processing unit that generates m divided frames and each of the m divided frames generated by the first signal processing unit are A first transmitter that transmits each of the m optical fibers to the second transponder at a transmission rate, wherein the second transponder transmits m transmissions from the first transmitter. A second receiving unit that receives each of the divided frames from each of the m optical fibers and a skew information included in each of the m divided frames received by the second receiving unit. A second signal processing unit that generates an OTU frame by combining each of the m divided frames received by the second receiving unit, and an OTU frame generated by the second signal processing unit. When error correction is performed In addition, a second signal conversion unit that extracts data of the specific format from the OTU frame generated by the second signal processing unit, and a specific format extracted by the second signal conversion unit And a second transmission unit for transmitting data at the first transmission rate.

The transmission system according to the third aspect of the present invention includes a first transponder that receives data of a specific format transmitted at a first transmission rate, and m + 1 (m is an integer of 2 or more) optical fibers. A transmission system including a second transponder connected to the first transponder, wherein the first transponder receives a specific type of data transmitted at the first transmission rate. 1 receiving unit, a first signal converting unit that generates an OTU frame storing data of a specific format received by the first receiving unit, and an OTU frame generated by the first signal converting unit Is divided into m predetermined frames in the column direction to generate m divided frames, and each of the m divided frames in the OTU frame is generated. A first signal processing unit that generates one skew information frame storing skew information indicating the arrangement position of each of the m divided frames generated by the first signal processing unit and one skew A first transmitter that transmits an information frame from each of the m + 1 optical fibers to the second transponder at a second transmission rate, wherein the second transponder includes the first transmitter A second receiving unit that receives each of the m divided frames and one skew information frame transmitted from each of the m + 1 optical fibers, and a skew information frame received by the second receiving unit. A second OTU frame is generated by combining each of the m divided frames received by the second receiving unit with reference to the skew information stored in the second receiving unit. A signal processor and error correction of the OTU frame generated by the second signal processor, and extracting the data of the specific format from the OTU frame generated by the second signal processor And a second transmission unit for transmitting data of a specific format extracted by the second signal conversion unit at the first transmission rate.

According to one aspect of the present invention, since the skew information indicating the arrangement position in the OTU frame is added to each divided frame divided based on the OTU frame, the transmission rate can be changed with a relatively small memory. Correspondingly, a signal can be divided and transmitted using a plurality of optical fibers.

1 is a schematic diagram of a transmission system according to Embodiments 1 to 4. FIG. 3 is a block diagram schematically showing a configuration of a transponder in the first and second embodiments. FIG. ITU-T Recommendation G. 7 is a schematic diagram showing a frame shape defined in 709. FIG. 3 is a block diagram schematically showing a configuration of a signal processing unit in the first and second embodiments. FIG. 6 is a schematic diagram for explaining processing in a data dividing unit according to Embodiment 1. FIG. FIG. 6 is a schematic diagram for explaining divided frames in the first embodiment. 3 is a block diagram illustrating an example of a hardware configuration of a transponder according to Embodiment 1. FIG. FIG. 11 is a schematic diagram for explaining divided frames in the second embodiment. 6 is a block diagram schematically showing a configuration of a signal processing unit in

Embodiments

3 and 4. FIG. 10 is a schematic diagram for explaining divided frames in Embodiment 3. FIG. FIG. 10 is a block diagram schematically showing a configuration of a transponder in a fourth embodiment. FIG. 10 is a schematic diagram for explaining a divided frame and a skew information frame in the fourth embodiment.

Embodiment 1 FIG.
FIG. 1 is a schematic diagram of a transmission system 100 according to the first embodiment.
The transmission system 100 includes a customer transmission device 110, a transponder 120, a transponder 130, a transponder 140, a transponder 150, and a customer transmission device 160.

A signal transmitted from the customer transmission device 110 is input to the transponder 120 and is output from the transponder 120 to the outside of the station.
The signal input to the transponder 130 is output to the transponder 140 by intra-station communication.
The signal input to the transponder 140 is output to the transponder 150 by communication outside the office.
The signal input to the transponder 150 is output to the customer transmission device 160.
Communication from the customer transmission device 110 to the customer transmission device 160 is performed through the network path 170.

The transponder 130 is connected to the transponder 120 connected to the customer transmission device 110, but the connection destination of the transponder 130 is not limited to such an example. For example, the transponder 130 may be connected to a transponder that performs other intra-station communication that can perform external communication.
Moreover, although the transponder 140 is connected to the transponder 150 connected to the customer transmission device 160, the connection destination of the transponder 140 is not limited to such an example. For example, the transponder 140 may be connected to a transponder that performs other intra-station communication that can perform external communication.
By performing such a connection, it is possible to connect a relay device that performs signal branching or insertion between the customer transmission device 110 and the customer transmission device 160 in multiple stages. In FIG. 1, the transponder 130 and the transponder 140 constitute such a relay device.

FIG. 2 is a block diagram schematically showing the configuration of the transponder 130 and the transponder 140.
The transponder 130 and the transponder 140 are connected by m (m is an integer of 2 or more) optical fibers 101 # 1 to 101 # m.
Embodiment 1 shows an example in which a signal is transmitted from transponder 130 to transponder 140. Here, the transmitting-side transponder 130 is also referred to as a first transponder, and the receiving-side transponder 140 is also referred to as a second transponder.

The transponder 130 includes an external I / F unit 131, a signal conversion unit 132, a signal processing unit 133, and a communication I / F unit 134.
The external I / F unit 131 is an interface that performs external communication. Here, the external I / F unit 131 receives an optical signal transmitted from the transponder 120 at a transmission rate of k Gbps, and has a specific format (first format) used in the external communication. Convert to electrical signals that represent data Here, k is an arbitrary number determined in advance. Here, the transmission rate of k Gbps is also referred to as a first transmission rate. In other words, the external I / F unit 131 functions as a first receiving unit that receives data of a specific format transmitted at the first transmission rate.

The signal conversion unit 132 stores the data indicated by the electrical signal supplied from the external I / F unit 131 in data of the data format (second format) for transmission at the transmission rate of n Gbps. , A first signal converter that generates data to be transmitted at a transmission rate of n Gbps. Here, n is a predetermined arbitrary number. Here, the transmission rate of n Gbps is also referred to as a second transmission rate.
For example, the signal conversion unit 132 converts the data indicated by the electrical signal transmitted from the I / F unit 131 for outside the office into the ITU-T Recommendation G. By storing in the OTU frame-shaped payload according to 709, an OTU frame that is data to be transmitted at a transmission rate of n Gbps is generated.

FIG. 3 shows ITU-T Recommendation G. 7 is a schematic diagram showing a frame shape defined in 709. FIG.
As shown in FIG. 3, the OTU frame 10 includes an area R1 for storing the OTU / ODU overhead 11, an area R2 for storing the payload 12, and an area R3 for storing the FEC data 13. And have.
The OTU / ODU overhead 11 is data including frame synchronization information, performance information, and monitoring information.
The payload 12 is data to be transmitted.
The FEC data 13 is Forward Error Correction (FEC) data for performing error correction when an error occurs.

The signal processing unit 133 illustrated in FIG. 2 processes the OTU frame generated by the signal conversion unit 132, thereby generating a first signal that generates m divided frames for transmission at a transmission rate of n Gbps. It is a processing unit. For example, the signal processing unit 133 deletes the FEC data from the OTU frame generated by the signal conversion unit 132 and divides it into m storage frames determined in advance in the column direction. Then, the signal processing unit 133 adds skew information indicating the arrangement position of each of the m storage frames in the OTU frame to the area where the FEC data is deleted in each of the m storage frames, so that m Generate divided frames.

FIG. 4 is a block diagram schematically showing the configuration of the signal processing unit 133.
The signal processing unit 133 includes an FEC data deletion unit 133a, a data division unit 133b, and a skew information addition unit 133c.
The FEC data deletion unit 133 a deletes the FEC data 183 in the OTU frame 10 given from the signal conversion unit 132. Then, the deleted frame is given to the data dividing unit 133b.

The data division unit 133b divides the frame given from the FEC data deletion unit 133a into m storage frames determined in advance.
FIG. 5 is a schematic diagram for explaining processing in the data dividing unit 133b.
As shown in FIG. 5, the data dividing unit 133b divides the frame 20 given from the FEC data deleting unit 133a into predetermined m frames in the column direction, so that the storage frame is divided. Generate. The storage frames divided here are in a data format for transmission at a transmission rate of n Gbps.

The skew information adding unit 133c shown in FIG. 4 stores each storage frame generated by the data dividing unit 133b in the area where the FEC data deleted by the FEC data deleting unit 133a is stored. By adding skew information for indicating the arrangement position of the frame, a divided frame is generated. The skew information is a number indicating the arrangement position in the frame 20 for each storage frame.
FIG. 6 is a schematic diagram for explaining divided frames.
As shown in FIG. 6, skew information is added to each of the divided frames in the area where the FEC data 183 is stored in the OTU frame 10.

The communication I / F unit 134 shown in FIG. 2 changes m divided frames subjected to frame processing to m optical signals, and converts each of the m optical signals to m optical fibers 101 # 1. Functions as a first transmission unit that transmits to each of the transponders 140 from 101 # m.
For example, the communication I / F unit 134 includes m client modules 135 # 1 to 135 # m that convert each of m divided frames into optical signals.

Next, the receiving transponder 140 will be described.
As shown in FIG. 2, the transponder 140 includes a communication I / F unit 141, a signal processing unit 143, a signal conversion unit 144, and an external I / F unit 145.
The communication I / F unit 141 receives each of the m optical signals from each of the m optical fibers 101 # 1 to 101 # m, and converts the m optical signals into m divided frames. , A second receiving unit that receives m divided frames. This divided frame has a data format for transmission at n Gbps.
For example, the communication I / F unit 141 includes m client modules 142 # 1 to 142 # m that convert each of m optical signals into divided frames.

The signal processing unit 143 refers to the skew information included in each of the m divided frames provided from the communication I / F unit 141, and each of the m divided frames provided from the communication I / F unit 141. 2 is a second signal processing unit that generates a frame obtained by combining the two. For example, the signal processing unit 143 refers to the skew information added to the divided frames of the m divided frames given from the communication I / F unit 141, and communicates with the communication I / F 134 and the communication I / F unit 141. The amount of delay generated in transmission between the two frames is calculated, the skew information is deleted from the divided frames, and the data lanes are aligned. Then, the signal processing unit 143 generates the frame 20 illustrated in FIG. 5 by combining the storage frames after the data lanes are aligned. Here, the frame 20 has a data format for transmission at a transmission rate of n Gbps.

The signal conversion unit 144 analyzes the frame 20 given from the signal processing unit 143, and extracts the data in a specific format that is stored in the payload of the frame 20 and is used for communication outside the station. It is a signal conversion part. Then, an electrical signal indicating the extracted data is given to the I / F unit 145 for outside the station. The electrical signal here is a signal for transmission at k Gbps used in communication outside the office.

The external I / F unit 145 is an interface that performs external communication. Here, the out-of-office I / F unit 145 converts the electrical signal of the transmission rate of k Gbps used in the out-of-office communication, which is given from the signal conversion unit 144, into an optical signal. Then, the external I / F unit 145 transmits the converted optical signal to the transponder 150 at a transmission rate of k Gbps. In other words, the external I / F unit 145 is a second transmission unit that transmits data in a specific format extracted by the signal conversion unit 144 at a first transmission rate of k Gbps.

As described above, since the signal processing unit 133 in the transponder 130 on the transmission side deletes only the FEC data 13 in the OTU frame 10, the kGbps electrical signal can be converted into the nGbps electrical signal while maintaining the OTU / ODU overhead 11. Stored in the signal and divided. Since the overhead 11 and the payload 12 are restored by the signal processor 143 of the transponder 130 on the reception side, transparent communication can be performed without adding processing to the overhead 11.

The transponders 130 and 140 described above include, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuits) or an FPGA as shown in FIG. (Field Programmable Gate Array) or the like.

In Embodiment 1, since each of the m divided frames has skew information, the signal processing unit 143 of the transponder 140 on the receiving side receives the m divided frames divided from one OTU frame. If received, the delay amount can be calculated and the data lanes can be aligned. For this reason, the transponder 130 and the transponder 140 can be realized by the processing circuit 180 using a memory smaller than the conventional technique using the OTL.

As described above, frame processing is performed by the transponder 130 and the transponder 140 between the stations, so that only the transponder 120 and the transponder 150 at the termination point are replaced with client transponders that match the transmission rate of the signal transmitted from the customer transmission device 110. Thus, the transponder 130 and the transponder 140 between the stations can transmit the data even if the transmission rate of the client data transmitted from the customer transmission device 110 changes while using the transponder in operation.

Embodiment 2. FIG.
As shown in FIG. 1, the transmission system 200 according to the second embodiment includes a customer transmission device 110, a transponder 120, a transponder 230, a transponder 240, a transponder 150, and a customer transmission device 160. .
The customer transmission device 110, the transponder 120, the transponder 150, and the customer transmission device 160 in the transmission system 200 according to the second embodiment are configured in the same manner as the transmission system 100 in the first embodiment.

As shown in FIG. 2, the transponder 230 according to the second embodiment includes an I / F unit 131 for outside the office, a signal conversion unit 132, a signal processing unit 233, and a communication I / F unit 134. .
The external I / F unit 131, the signal conversion unit 132, and the communication I / F unit 134 of the transponder 230 in the second embodiment are configured in the same manner as the transponder 130 in the first embodiment.

As shown in FIG. 4, the signal processing unit 233 according to the second embodiment includes an FEC data deletion unit 133a, a data division unit 133b, and a skew information addition unit 233c.
The FEC data deletion unit 133a and the data division unit 133b of the signal processing unit 233 in the second embodiment are configured in the same manner as the signal processing unit 133 in the first embodiment.

The skew information adding unit 233c calculates a bit interleaved parity (BIP-8), which is an error detection code, from each storage frame generated by the data dividing unit 133b. For example, as shown in FIG. 8, the skew information adding unit 233c stores the FEC data deleted by the FEC data deleting unit 133a in each storage frame generated by the data dividing unit 133b. By adding an error detection code (BIP-8) and skew information to the area, a divided frame is generated.

As shown in FIG. 2, the transponder 240 according to the second embodiment includes a communication I / F unit 141, a signal processing unit 243, a signal conversion unit 144, and an external I / F unit 145. .
The communication I / F unit 141, the signal conversion unit 144, and the external I / F unit 145 of the transponder 240 in the second embodiment are configured in the same manner as the transponder 140 in the first embodiment.

The signal processing unit 243 according to the second embodiment performs error detection on the m divided frames provided from the communication I / F unit 141 using an error detection code added to each divided frame.
In addition, the signal processing unit 243 refers to the skew information added to the divided frames of the m divided frames given from the communication I / F unit 141, and communicates with the communication I / F 134 and the communication I / F unit 141. A delay amount generated in transmission between the data lanes is calculated, error detection codes and skew information are deleted from the divided frames, and the data lanes are aligned. Then, the signal processing unit 243 generates the frame 20 illustrated in FIG. 5 by combining the storage frames after the data lanes are aligned. Here, the frame 20 has a data format for transmission at a transmission rate of n Gbps.

As described above, in the second embodiment, the number of errors generated during transmission between the communication I / F 134 and the communication I / F unit 141 can be calculated by adding an error detection code. For this reason, Embodiment 2 can investigate the transmission quality of communication.

Embodiment 3 FIG.
As shown in FIG. 1, a transmission system 300 according to the third embodiment includes a customer transmission device 110, a transponder 120, a transponder 330, a transponder 340, a transponder 150, and a customer transmission device 160. .
The customer transmission device 110, the transponder 120, the transponder 150, and the customer transmission device 160 in the transmission system 300 according to the third embodiment are configured in the same manner as the transmission system 100 in the first embodiment.

As shown in FIG. 2, the transponder 330 according to the third embodiment includes an external I / F unit 131, a signal conversion unit 132, a signal processing unit 333, and a communication I / F unit 134. .
The external I / F unit 131, the signal conversion unit 132, and the communication I / F unit 134 of the transponder 330 in the third embodiment are configured in the same manner as the transponder 130 in the first embodiment.

The signal processing unit 333 divides the OTU frame generated by the signal conversion unit 132 into predetermined m storage frames in the column direction, and adds an OTU frame at the end of each of these m storage frames. Is a first signal processing unit that generates m divided frames by adding skew information indicating the arrangement positions of each of these m storage frames.

FIG. 9 is a block diagram schematically showing the configuration of the signal processing unit 333.
The signal processing unit 333 includes a data dividing unit 333b and a skew information adding unit 333c.
The signal processing unit 333 in the third embodiment does not delete the FEC data 183 from the OTU frame 10.

The data dividing unit 333b divides the OTU frame 10 given from the signal converting unit 132 into predetermined m storage frames. The storage frames divided here are in a data format for transmission at a transmission rate of n Gbps.

As shown in FIG. 10, the skew information adding unit 333c generates a divided frame by adding skew information to each storage frame generated by the data dividing unit 133b.

As shown in FIG. 2, the transponder 340 according to the third embodiment includes a communication I / F unit 141, a signal processing unit 343, a signal conversion unit 344, and an external I / F unit 145. .
The communication I / F unit 141 and the external I / F unit 145 of the transponder 340 in the third embodiment are configured in the same manner as the transponder 140 in the first embodiment.

The signal processing unit 343 according to the second embodiment refers to the skew information included in each of the m divided frames provided from the communication I / F unit 141 and combines each of these m divided frames. By doing so, the second signal processing unit generates an OTU frame.
For example, the signal processing unit 343 refers to the skew information added to each of the m divided frames given from the communication I / F unit 141 with reference to the skew information added to the divided frames, and the communication I / F unit 141. The amount of delay generated in transmission between the two frames is calculated, the skew information is deleted from the divided frames, and the data lanes are aligned. Then, the signal processing unit 243 generates the OTU frame 10 illustrated in FIG. 3 by combining the storage frames after the data lanes are aligned. Here, the OTU frame 10 has a data format for transmission at a transmission rate of n Gbps.

The signal conversion unit 344 performs error correction of the OTU frame 10 using the FEC data 13 included in the OTU frame 10 given from the signal processing unit 343.
Then, the signal conversion unit 344 analyzes the error-corrected OTU frame 10 and extracts data in a specific format that is stored in the payload 12 and is used for communication outside the office. Then, an electrical signal indicating the extracted data is given to the I / F unit 145 for outside the station.

As described above, in the third embodiment, since the FEC data 13 is included in the OTU frame 10 that is restored on the receiving side, error correction is performed when a data error occurs during transmission between stations. Is possible.
Further, since the FEC data 13 is not deleted in the third embodiment compared to the first embodiment, the transmission rate of the signal output from the client module is increased, but a circuit for deleting the FEC data is not necessary. The circuit scale can be reduced.

Embodiment 4 FIG.
As shown in FIG. 1, the transmission system 400 according to the fourth embodiment includes a customer transmission device 110, a transponder 120, a transponder 430, a transponder 440, a transponder 150, and a customer transmission device 160. .
The customer transmission device 110, the transponder 120, the transponder 150, and the customer transmission device 160 in the transmission system 400 according to the fourth embodiment are configured in the same manner as the transmission system 100 in the first embodiment.

FIG. 11 is a block diagram schematically showing configurations of transponder 430 and transponder 440 in the fourth embodiment.
Here, the transponder 430 and the transponder 440 in the fourth embodiment are connected by m + 1 optical fibers.
The transponder 430 includes an external I / F unit 131, a signal conversion unit 132, a signal processing unit 433, and a communication I / F unit 434.
The external I / F unit 131 and the signal conversion unit 132 of the transponder 430 in the fourth embodiment are configured in the same manner as the transponder 130 in the first embodiment.

The signal processing unit 433 according to the fourth embodiment generates m divided frames by dividing the OTU frame provided from the signal conversion unit 132 into predetermined m frames in the column direction. A first signal processing unit that generates one skew information frame storing skew information indicating the arrangement position of each of the m divided frames in the OTU frame.

As shown in FIG. 9, the signal processing unit 433 according to the fourth embodiment includes a data dividing unit 333b and a skew information adding unit 433c.
The data dividing unit 333b of the signal processing unit 433 in the fourth embodiment is configured similarly to the signal processing unit 333 in the third embodiment.

The skew information adding unit 433c generates a skew information frame including skew information indicating the arrangement position of each storage frame generated by the data dividing unit 333b. Then, as shown in FIG. 12, the skew information adding unit 433c sets the m storage frames generated by the data dividing unit 333b to m divided frames, and adds the skew information frame FL # to the divided frames. The added m + 1 frames are given to the communication I / F unit 434. Here, it is assumed that skew information of predetermined divided frames is stored in the skew information frame in a predetermined order.

The communication I / F unit 434 illustrated in FIG. 11 changes m divided frames and one skew information frame subjected to frame processing to m + 1 optical signals, and converts m + 1 optical signals to m + 1. Transmission is performed from the optical fibers 101 # 1 to 101 # m + 1 to the transponder 440.
For example, the communication I / F unit 434 includes m + 1 client modules 435 # 1 to 435 # m + 1 that convert each of m divided frames and one skew information frame into an optical signal.

As shown in FIG. 11, the transponder 440 according to the fourth embodiment includes a communication I / F unit 441, a signal processing unit 443, a signal conversion unit 344, and an external I / F unit 145. .
The signal conversion unit 344 of the transponder 440 in the fourth embodiment is configured in the same manner as the transponder 340 in the third embodiment.
The external I / F unit 145 of the transponder 440 in the fourth embodiment is configured in the same manner as the transponder 140 in the first embodiment.

The communication I / F unit 441 according to the fourth embodiment receives m + 1 optical signals from m + 1 optical fibers 101 # 1 to 101 # m + 1, converts m optical signals into m divided frames, and The remaining one optical signal is converted into a skew information frame. This divided frame has a data format to be transmitted at a transmission rate of n Gbps.
For example, the communication I / F unit 441 converts m client modules 442 # 1 to 442 # m that convert each of m optical signals into divided frames, and converts the remaining one optical signal into a skew information frame. Client module 442 # m + 1.

The signal processing unit 443 according to the fourth embodiment refers to the skew information stored in the skew information frame provided from the communication I / F unit 441, and determines m divided frames provided from the communication I / F unit 441. It is the 2nd signal processing part which produces | generates an OTU frame by combining each.
For example, the signal processing unit 443 refers to the m pieces of divided frames provided from the communication I / F unit 441 with reference to the skew information included in the skew information frame provided from the communication I / F unit 441. The amount of delay generated in transmission between / F434 and communication I / F unit 441 is calculated, and the data lanes are aligned. Then, the signal processing unit 243 generates the OTU frame 10 illustrated in FIG. 3 by combining the divided frames after the data lanes are aligned. Here, the OTU frame 10 has a data format for transmission at a transmission rate of n Gbps.
Since the skew information becomes unnecessary after the data lanes are aligned, the signal processing unit 443 discards the information.

As described above, in the fourth embodiment, similarly to the third embodiment, the FEC data 13 is included in the divided frames, so that error correction can be performed by the transponder 440 on the receiving side. On the other hand, in the fourth embodiment, the transmission rate of the frame output from the communication I / F unit 434 can be made lower than that in the third embodiment.

100, 200, 300, 400 transmission system, 101 optical fiber, 110 customer transmission device, 120 transponder, 130, 230, 330, 430 transponder, 131 I / F unit for outside the station, 132 signal conversion unit, 133, 233, 333 433 signal processing unit, 133a FEC data deletion unit, 133b data division unit, 133c, 233c, 433c skew information addition unit, 134, 434 communication I / F unit, 135, 435 client module, 140, 240, 340, 440 transponder, 141,441 communication I / F unit, 142,442 client module, 143,243,343,443 signal processing unit, 144,344 signal conversion unit, 145 out of station Only I / F unit 150 transponder 160 customers transmission apparatus 180 processing circuits.

Claims

A first transponder that receives data of a specific format transmitted at a first transmission rate, and a second transponder connected to the first transponder by m optical fibers (m is an integer of 2 or more) A transmission system including a transponder of
The first transponder is:
A first receiver for receiving data of a specific format transmitted at the first transmission rate;
A first signal converter that generates an OTU frame storing data of a specific format received by the first receiver;
The FEC data is deleted from the OTU frame generated by the first signal conversion unit, and is divided into m storage frames determined in advance in the column direction, and the FEC data in each of the m storage frames. A first signal processing unit that generates m divided frames by adding skew information indicating the arrangement position of each of the m storage frames in the OTU frame to the area where is deleted,
A first transmission unit configured to transmit each of the m divided frames generated by the first signal processing unit from each of the m optical fibers to the second transponder at a second transmission rate; With
The second transponder is
A second receiver that receives each of the m divided frames transmitted from the first transmitter from each of the m optical fibers;
A frame obtained by combining each of the m divided frames received by the second receiving unit with reference to skew information included in each of the m divided frames received by the second receiving unit. A second signal processing unit for generating
A second signal conversion unit that extracts data of the specific format from the frame generated by the second signal processing unit;
A transmission system comprising: a second transmission unit configured to transmit data of a specific format extracted by the second signal conversion unit at the first transmission rate.
In addition to the skew information, the first signal processing unit adds an error detection code calculated from each of the m storage frames to the area where the FEC data has been deleted,
The second signal processing unit performs error detection using an error detection code included in each of m divided frames received by the second receiving unit. The transmission system described in 1.
A first transponder that receives data of a specific format transmitted at a first transmission rate, and a second transponder connected to the first transponder by m optical fibers (m is an integer of 2 or more) A transmission system including a transponder of
The first transponder is:
A first receiver for receiving data of a specific format transmitted at the first transmission rate;
A first signal converter that generates an OTU frame storing data of a specific format received by the first receiver;
The OTU frame generated by the first signal conversion unit is divided into predetermined m storage frames in the column direction, and the m in the OTU frame is added to the end of each of the m storage frames. A first signal processing unit that generates m divided frames by adding skew information indicating an array position of each of the storage frames;
A first transmission unit configured to transmit each of the m divided frames generated by the first signal processing unit from each of the m optical fibers to the second transponder at a second transmission rate; With
The second transponder is
A second receiver that receives each of the m divided frames transmitted from the first transmitter from each of the m optical fibers;
Referencing skew information included in each of m divided frames received by the second receiving unit, and combining each of the m divided frames received by the second receiving unit. A second signal processing unit for generating an OTU frame by:
A second signal conversion unit that performs error correction of the OTU frame generated by the second signal processing unit and extracts data of the specific format from the OTU frame generated by the second signal processing unit; ,
A transmission system comprising: a second transmission unit configured to transmit data of a specific format extracted by the second signal conversion unit at the first transmission rate.
A first transponder that receives data of a specific format transmitted at a first transmission rate, and a second transponder connected to the first transponder by m + 1 (m is an integer of 2 or more) optical fibers. A transmission system including a transponder of
The first transponder is:
A first receiver for receiving data of a specific format transmitted at the first transmission rate;
A first signal converter that generates an OTU frame storing data of a specific format received by the first receiver;
The OTU frame generated by the first signal conversion unit is divided into m predetermined frames in the column direction, thereby generating m divided frames and the m frames in the OTU frame. A first signal processing unit for generating one skew information frame storing skew information indicating the arrangement position of each of the divided frames;
Each of the m divided frames and one skew information frame generated by the first signal processing unit is transmitted from each of the m + 1 optical fibers to the second transponder at a second transmission rate. A first transmission unit,
The second transponder is
A second receiving unit that receives each of m divided frames and one skew information frame transmitted from the first transmitting unit from each of the m + 1 optical fibers;
By referring to the skew information stored in the skew information frame received by the second receiving unit, the OTU frame is obtained by combining each of the m divided frames received by the second receiving unit. A second signal processor to generate;
A second signal conversion unit that performs error correction of the OTU frame generated by the second signal processing unit and extracts data of the specific format from the OTU frame generated by the second signal processing unit When,
A transmission system comprising: a second transmission unit configured to transmit data of a specific format extracted by the second signal conversion unit at the first transmission rate.