JP2008219382A - Data transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inform a link-trouble occurrence without shutting down an optical output regarding a data transmission system transmitting data at 10 Gbps. <P>SOLUTION: In the data transmission system, a plurality of networks 10A and 10B are connected through a plurality of transmitters 12A and 12B and data are transmitted at a data transmission rate of 10 Gbps. The transmitters 12A and 12B have means generating local faults LF and transmitting the local faults LF to the network side by the reception and detection of either of a BER alarm/an LOF alarm/an LOS alarm/an SF alarm by the link-trouble occurrence from the transmitters oppositely connected through a transmission line. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a data transmission system that performs data transmission at a data transmission rate of 10 Gbps or higher.

  Various systems are known that perform data transmission at a transmission rate of 10 Gbps using optical signals. For example, FIG. 9 shows a main part of the example, and is an explanatory diagram of a conventional example when a failure occurs. 100A and 100B are 10 Gbps called 802.3ae and 10 Gigabit Ethernet (registered trademark). A transmission speed network, 101A to 101D denote termination devices, and 102A to 102D denote transmission devices. A transmission path between the networks 100A and 100B via the termination device 101A, the transmission devices 102A and 102B, and the termination device 101B. The terminal device 101C, the transmission devices 102C and 102D, and the transmission device via the terminal device 101D are connected to each other, and one transmission route is used as the active system and the other transmission route is used as the standby system.

  When data is transmitted between the networks 100A and 100B using the transmission path between the terminal device 101A connected to the network 100A and the terminal device 101B connected to the network 100B as an active system, the transmission devices 102A and 102B In the relay section between the NTWK (network) side, as shown by the x mark, when the link breakage occurs, the occurrence of link breakage is detected due to a decrease in received light level at the NTWK side end of the transmission device 102B. , A link disconnection detection notification is sent to the terminal on the CLNT (client) side. As a result, the CLNT side performs optical output shutdown, as indicated by black circles and crosses, and notifies the termination device 101B of the occurrence of link disconnection. In addition, the transmission apparatus 102B notifies the transmission apparatus 102A that a link has been disconnected. In response to the link disconnection occurrence notification, the transmission apparatus 102A performs an optical output shutdown to the termination apparatus 100A and notifies the occurrence of link disconnection in the relay section, as indicated by the black circle mark and the X mark on the CLNT side. The terminating devices 101A and 101B detect the optical output shutdown on the CLNT side of the transmission devices 102A and 102B, respectively, recognize the occurrence of the link break in the relay section, and notify the terminating devices 101C and 101D, respectively, thereby providing the networks 100A and 101D. The transmission path between 100B can be switched from the active system to the standby system.

In order to avoid a link disconnection occurrence notification due to a forced optical output shutdown as much as possible, means for performing a link disconnection occurrence notification using a maintenance frame has been proposed. For example, in the relay section between the transmission apparatuses 102A and 102B in FIG. 9, when a link break indicated by x is detected, the occurrence of the link break is detected on the transmission apparatus 102B side, The output is shut down, and the forcible link disconnection start is notified by a maintenance frame to the transmission apparatus 102A that is oppositely connected via the relay section. There has been proposed a system and a control method for controlling the transmission apparatus 102A that has received the forced link disconnection start notification so as not to perform the forced link disconnection with respect to the terminating apparatus 101A (see, for example, Patent Document 1).
JP 2005-33665 A

  In the conventional example of notifying the occurrence of failure by optical output shutdown when a failure occurrence such as link breakage is detected, it can be notified by a relatively simple control process. This is performed by stopping the operation of the light source. The light output of the optical module does not instantaneously drop to zero level by the start of the light output shutdown, and requires at least about 100 μs. The optical output shutdown time conforming to the unified standard is 110 μs at maximum (for 1,618 frames). Similarly, at the start of the operation of the optical module, a similar period is required for the optical output level to rise to a predetermined level. Therefore, there is a problem that the time required for the link failure notification due to the optical output shutdown becomes longer, and similarly, the time required for the failure recovery notification becomes longer.

  Also, as optical modules, 300pin, XENPAK, X2, XFP, etc. are known, and XFP of them can convert 10Gbps electrical signals directly into optical signals, but the optical output level However, when recovering from a forced shutdown, about 60 s is required. That is, there is a problem that data loss becomes large in the case of high-speed transmission in which the time from the forced shutdown to returning to the original state exceeds 10 Gbps. Furthermore, the optical module is vulnerable to electrical and mechanical shocks, and there is a problem that characteristic deterioration proceeds due to repeated operation start and operation stop.

  An object of the present invention is to solve the above-mentioned conventional problems and to promptly notify the occurrence of a failure in a high-speed transmission line such as 10 Gbps.

  The data transmission system of the present invention is a data transmission system in which a plurality of networks are connected via a plurality of transmission devices, and data is transmitted at a data transmission rate of 10 Gbps. The transmission device is connected via the transmission path. And a means for generating a local fault and sending it to the network side upon detection of reception of a BER alarm / LOF alarm / LOS alarm / SF alarm due to the occurrence of a link failure from the connected opposite transmission apparatus.

  Further, in a data transmission system in which a plurality of networks are connected via a plurality of transmission apparatuses and data is transmitted at a data transmission rate of 10 Gbps, the transmission apparatus is connected to the opposite transmission apparatus via the transmission path. And a means for generating a local fault and sending it to the network side upon detection of reception of a BER back alarm / LOF back alarm / LOS back alarm / SF back alarm due to a link failure with the network.

  BER alarm due to bit error rate increase, LOF alarm due to loss of frame synchronization, LOS alarm due to signal loss, notification of link failure occurrence due to SF alarm due to frame loss, or BER back alarm, LOF back alarm, LOS back alarm, SF back alarm By generating and sending a local fault LF by notifying the occurrence of a link failure, it is possible to notify the opposite device side at a higher speed than when notifying the occurrence of a link failure due to optical output shutdown, and By not performing output shutdown, the operation of the optical module can be stabilized and the life can be extended.

  The data transmission system of the present invention will be described with reference to FIG. 1. Data transmission in which a plurality of networks 10A and 10B are connected via a plurality of transmission devices 12A and 12B and data is transmitted at a data transmission rate of 10 Gbps. In this system, the transmission devices 12A and 12B generate a local fault LF by detecting reception of a BER alarm / LOF alarm / LOS alarm / SF alarm due to the occurrence of a link failure from the opposite transmission device connected via the transmission path. Means for sending to the network side.

  FIG. 1 is an explanatory diagram of Embodiment 1 of the present invention, 10A and 10B are networks of 10 Gbps or higher transmission speed such as 10G Ethernet (registered trademark), 11A to 11D are termination devices, and 12A to 12D are transmissions. Devices 13A to 13D indicate client side termination units, between the termination units 13A to 13D of the transmission devices 12A to 12D and the termination devices 11A to 11D of the networks 10A and 10B, and between the transmission devices 12A and 12B. The devices 12C and 12D are connected by optical transmission lines, respectively, and have a configuration for performing data transmission at the same transmission speed as the networks 10A and 10B.

  Further, a link fault notification LFS (Link Fault Signaling) continuously transmits a local fault LF (Local Fault) to the downstream side of the data flow by detecting the occurrence of link breakage, and upon receiving this LF, a remote fault RF (Remote Remote) is received. (Fault) is continuously returned and notified, and the occurrence of link disconnection is recognized by continuously receiving the LF code in this case three times. The required time in this case is about 10 ns at a transmission rate of 10 Gbps. Further, when the link break is released by the LF code, the normal code is continuously received 128 times, and the required time in this case is about 410 ns.

Therefore, in FIG. 1, for example, the termination unit 13B of the transmission apparatus 12B receives data from the termination apparatus 11B, and indicates (1) BER (Bit Error Rate) detection due to some link failure. As described above, when it is detected that the transmission bit error rate has reached a predetermined value of, for example, 10 ⁻¹² or more, the termination unit 13B sends the counter transmission device 12A via the transmission path to the opposite transmission apparatus 12A as shown in (2) BER occurrence notification A BER alarm is notified, and (3) RF is generated and transmitted to the terminating device 11B of the network 10B, as shown as RF transmission. In addition, as shown in (4) line switching, line switching processing is started. When the transmission device 12A receives and detects the BER alarm from the transmission device 12B, as shown in (5) LF generation + transmission, the transmission device 12A sends LF from the termination unit 13A to the termination device 11A on the network 10A side, (6) As shown in the line switching, the terminal device 11C is notified of the line switching, and (7) as shown in the RF transmission, the RF is sent to the terminal unit 13A of the transmission device 12A.

  Thereby, the working transmission path between the terminal devices 11A and 11B can be switched to the standby transmission path between the terminal devices 11C and 11D, and data transmission between the networks 10A and 10B can be continued. As described above, an increase in the transmission bit error rate due to a link failure is detected and a BER alarm is notified to the opposite device, and the opposite transmission device generates LF and notifies the occurrence of the link failure without shutting down the optical output. Therefore, it is possible to promptly notify the occurrence of a link failure, thereby quickly switching the transmission path from the active system to the standby system between the networks 10A and 10B.

  FIG. 2 shows a configuration of a main part of the transmission apparatus, and a failure state and a failure on one of LOS (Loss of Signal) / LOF (Loss of Frame) / BER (Bit Error Rate) / SF (Short Frame) on the CLNT side. When notification is detected, it is explanatory drawing in the case of generating and sending out LF / RF for link failure occurrence notification, 12 is a transmission device, 21 is a termination unit on the CLNT side, and 22 is a main signal processing unit , 23 are NTWK side termination units, 24 is a monitoring / control unit, 25 and 27 are physical layer termination units, and 26 and 28 are MAC termination units. The CLNT side termination unit 21 is a termination unit on the side connected to any of the termination units 11A to 11D in FIG. 1, and the NTWK side termination unit 23 is connected to the opposite transmission apparatus via a transmission line. This is the end of the side. The monitoring / control unit 24 controls each unit.

  The physical layer termination units 25 and 28 of the termination units 21 and 23 perform transmission / reception processing on the CLNT side and the NTWK side, and the MAC termination units 26 and 27 have an LF or RF generation function. Reference numeral 24 denotes a case where it has a function of performing control processing in the arrow direction according to the reception detection result. For example, when the physical layer termination unit 25 on the CLNT side notifies the monitoring / control unit 24 of reception detection of any one of LOS / LOF / BER / SF, the monitoring / control unit 24 notifies the MAC termination unit 27 Then, the LF generation and transmission are instructed. As a result, the physical layer termination unit 27 on the NTWK side generates LF and sends it out from the physical layer termination unit 28.

  FIG. 3 shows a main part of the transmission apparatus having the same configuration as that in FIG. 2, and is an explanatory diagram when the processing flow is different from the case shown in FIG. 2, and the physical layer termination unit 28 of the termination unit 23 on the NTWK side. When the LOS / LOF / BER / SF is received and detected, the monitoring / control unit 24 is notified. The monitoring / control unit 24 notifies the MAC termination unit 26 of the termination unit 21 on the CLNT side, and the MAC termination unit 26 is notified. Generates an LF and sends the LF from the physical layer termination unit 25 on the CLNT side.

  FIG. 4 is an explanatory diagram of the operation at the time of receiving the LOF alarm, and the same reference numerals as those in FIG. 1 indicate the same parts. In the termination unit 13B of the transmission device 12B, due to a link failure with the termination device 11B, (1) as shown as LOF detection, and (2) as shown as LOF occurrence notification, as shown in LOF detection. The counter transmission device 12A connected through the network 10B is notified of the LOF alarm, and as shown in (3) RF transmission, the RF is generated and transmitted to the terminating device 11B on the network 10B side, (4) As shown as line switching, line switching is started. Also, the transmission apparatus 12A receives and detects the LOF alarm from the transmission apparatus 12B, and generates and sends the LF from the termination unit 13A to the termination apparatus 11A on the network 10A side as shown in (5) LF generation + transmission. To do. Further, the terminal device 11A starts line switching as shown in (6) line switching. As a result, the transmission path between the networks 10A and 10B can be switched from the active system to the standby system. Therefore, when an LOF is detected due to the occurrence of a link failure, the occurrence of a link failure can be quickly notified to the opposite device using LF without performing an optical output shutdown.

  FIG. 5 is a diagram for explaining the operation at the time of receiving the LOS alarm, and the same reference numerals as those in FIG. 1 denote the same parts. In the terminal unit 13B of the transmission apparatus 12B, (1) LOS detection as one of the link failures as shown as LOS detection, (2) LOS to the transmission apparatus 12A as shown as LOS occurrence notification Create an alarm. In addition, as shown in (3) RF transmission, RF is transmitted to the terminating device 11B, and (4) line switching is started as shown in line switching. The transmission device 11A receives and detects the LOS alarm, and sends LF to the terminal device 11A as shown in (5) LF sending. The terminal device 11A starts line switching as indicated by (6) line switching, and sends RF to the transmission apparatus 12A as indicated by (7) RF transmission. In this case, the terminating device 11B starts line switching when RF reception is detected, and the terminating device 11A starts line switching when LF reception is detected, and switches from the active transmission path to the standby transmission path. Data transmission between 10A and 10B can be continued.

  FIG. 6 is a diagram for explaining the operation at the time of SF back alarm reception. The same reference numerals as those in FIG. 1 denote the same parts. In the transmission apparatus 12A, as shown in (1) SF detection, the SF detection as one of the link faults notifies the transmission apparatus 12B of (2) SF occurrence as shown in the SF occurrence notification. To do. As shown in (3) SF back alarm detection, when the transmission device 12B receives and detects the SF back alarm from the transmission device 12A, the terminal unit 13B sends (4) LF generation + transmission to the terminal device 11B. As shown, the LF is generated and sent out. The terminating device 11B that has received this LF sends RF to the terminating unit 13B of the transmission device 12B, and as shown in (5) RF detection, the terminating unit 13B receives and detects RF, and (6) shows as line switching. Thus, the line switching is started. Further, the transmission apparatus 12A generates and transmits LF to the terminal apparatus 11A together with the SF generation notification to the transmission apparatus 12B as shown in (4) LF generation + transmission. The terminal device 11A starts line switching as indicated by (6) line switching upon reception of LF from the transmission apparatus 12A. As a result, SF detection due to link failure makes it possible to promptly notify using LF without shutting down optical output, switch the transmission path from the active system to the standby system, and continue data transmission between networks 10A and 10B. can do.

  FIG. 7 is a diagram for explaining the operation at the time of receiving the LOF back alarm. The same reference numerals as those in FIG. 1 denote the same parts. When the LOF is detected in the transmission apparatus 12A as shown in (1) LOF detection, 2) Notify the transmission device 12B of the occurrence of LOF, as shown as the LOF occurrence notification. When the transmission device 12B receives and detects the LOF occurrence notification from the transmission device 12A as shown in (3) LOF back alarm detection, (4) the terminal device 13B terminates from the terminal unit 13B as shown as LF generation + transmission. Send LF to 11B. The terminating device 11B transmits RF to the transmission device 12B. (5) As shown as RF detection, the terminating device 11B receives and detects RF, and (6) Line switching as shown as line switching. To start. The transmission apparatus 11A generates LF by detecting the LOF as shown in (4) LF generation + transmission and sends it to the terminal apparatus 11A, and (6) starts line switching as shown as line switching. Thereby, the transmission path can be switched from the active system to the standby system, and data transmission between the networks 10A and 10B can be continued.

  FIG. 8 is a diagram for explaining the operation at the time of receiving the LOS back alarm, and the same reference numerals as those in FIG. 1 denote the same parts. In the transmission apparatus 12A, when LOS is detected as shown in (1) LOS detection, (2) LOS generation is notified to the transmission apparatus 12B as shown as LOS occurrence notification. The transmission device 12B receives and detects the LOS occurrence notification from the transmission device 12A as shown in (3) LOS back alarm detection, and (4) generates LF as shown in LF generation + transmission to terminate the termination device. 11B. The terminating device 11B generates RF and sends it to the transmission device 12B. The transmission device 12B receives and detects the RF from the termination device 11B as shown in (5) RF detection, and starts line switching as shown in (6) line switching. The transmission apparatus 12A generates and creates LF as shown in (4) LF generation + transmission to the termination apparatus 11A. The termination apparatus 11A transmits RF to the transmission apparatus 12A. The transmission device 12A receives and detects the RF from the termination device 11A as shown in (5) RF detection, and starts line switching as shown in (6) line switching. Thereby, the transmission path can be switched from the active system to the standby system, and data transmission between the networks 10A and 10B can be continued.

  Also, when receiving and detecting an alarm and back alarm due to any of the above link failures of LOS / LOF / BER / SF, generating an LF and notifying the occurrence of a link failure, It is also possible to notify, but when link failure notification enabled / disabled is set in advance to correspond to the type of link failure, and link failure occurrence with valid settings is detected, link failure occurs due to RF together with LF as described above It is also possible to adopt a configuration that notifies

It is explanatory drawing of Example 1 of this invention. It is explanatory drawing of a structure and processing operation | movement of the transmission apparatus of Example 1 of this invention. It is explanatory drawing of a structure and processing operation | movement of the transmission apparatus of Example 1 of this invention. It is operation | movement explanatory drawing at the time of LOF alarm reception of Example 1 of this invention. It is operation | movement explanatory drawing at the time of LOS alarm reception of Example 1 of this invention. It is operation | movement explanatory drawing at the time of SF back alarm reception of Example 1 of this invention. It is operation | movement explanatory drawing at the time of LOF back alarm reception of Example 1 of this invention. It is operation | movement explanatory drawing at the time of LOS back alarm reception of Example 1 of this invention. It is explanatory drawing of a prior art example.

Explanation of symbols

10A, 10B network 11A to 11D terminator 12A to 12D transmission device 13A to 13D terminator 12 transmission device 21, 23 terminator 22 main signal processing unit 24 monitoring / control unit 25, 28 physical layer terminator 26, 27 MAC terminator

Claims (2)

In a data transmission system in which a plurality of networks are connected via a plurality of transmission devices and data is transmitted at a data transmission rate of 10 Gbps.
The transmission apparatus generates a local fault and sends it to the network side upon detection of reception of a BER alarm / LOF alarm / LOS alarm / SF alarm due to the occurrence of a link failure from the opposite transmission apparatus connected via the transmission path. A data transmission system comprising means. In a data transmission system in which a plurality of networks are connected via a plurality of transmission devices and data is transmitted at a data transmission rate of 10 Gbps.
The transmission apparatus generates a local fault by detecting reception of a BER back alarm / LOF back alarm / LOS back alarm / SF back alarm due to a link failure with the opposite transmission apparatus connected via the transmission path, and A data transmission system comprising means for sending to the network side.

Images