JP2012034030A - Communication device and route switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication device capable of preventing a link-down from occurring during route switching in a gigabit Ethernet protection configuration.SOLUTION: Comma signal generation means 81 generates a comma signal that is data used in code synchronization based on a ratio of a code included in a transmission signal. Operation state determination means 82 determines that the operation state of one of signal transmission means is an active system and the operation state of the other signal transmission means is a standby system based on the line quality of a connected line. Signal selection means 83 selects either one of the transmission signal and the comma signal as a signal to be transmitted to other devices. Clock signal synchronization means 84 synchronizes a clock signal used to transmit the signal selected by the signal selection means 83 with a clock signal generated by other signal transmission means. Selection signal transmission means 85 transmits the signal selected by the signal selection means 83 to other devices according to the clock signal synchronized by the clock signal synchronization means 84.

Description

  The present invention relates to a communication device connected to a ring network and a route switching method in the communication device.

  There is a UPSR (Unidirectional Path Switched Ring) system as a gigabit Ethernet (registered trademark: GbE) ring or ring-type SONET (Synchronous Optical NETwork) / SDH (Synchronous Digital Hierarchy) protection (switching) system. . In the UPSR system, node devices (switches) connected to the ring normally output the same signal as the active system and the standby system from both directions of the ring. Then, the node device receives a signal from the working ring and switches the standby system to the working system when a failure occurs in the working system.

  Patent Document 1 describes an optical network based on the USPR method. In the optical network described in Patent Document 1, one fiber is used in each of the clockwise and counterclockwise directions, and one of the signals flowing through each fiber is an active system, and the other signal is a standby system. Used as Then, each node rescues signal transmission in the failed section by switching to receive a backup signal in the reverse direction when a failure occurs in the active system.

  Patent Document 2 describes a method for notifying a link disconnection state of a line. In the method described in Patent Literature 2, the output of the optical signal to the counter optical transmission device is stopped using the media converter detecting the disconnection state of the receiving circuit as a trigger. When the opposite optical transmission device detects the disconnection state of the optical line, it performs link disconnection processing and switches the communication path to a bypass route.

  In addition, in communication by GbE, there is GMII (Gigabit Media Independent Interface) as an interface that connects a MAC (Media Access Control) layer and a physical layer. Non-Patent Document 1 describes the flow of data transmitted to the physical layer via GMII. Data transmitted to the physical layer via GMII is encoded by a PCS (Physical Coding Sublayer) layer and transmitted to a PMA (Physical Media Attachment) layer. Hereinafter, a signal transmitted from the PCS layer to the PMA layer is referred to as “tx_code-group <9: 0>” in accordance with the notation described in Non-Patent Document 1 (see FIG. 36-2 in Non-Patent Document 1). This signal is 10-bit data encoded by 10B. This signal is defined for transmission processing in the PCS layer, and is transmitted as a parameter used in the PMA layer service.

  Further, the PMA layer performs parallel-serial conversion on the received signal (see FIG. 36-10 in Non-Patent Document 1). Specifically, when a signal is transmitted to the PMA layer, a parallel in serial out (PISO) converts the parallel signal into a serial signal in a TBI (Ten-Bit Interface) of the PMA layer. At this time, the PISO performs parallel-serial conversion in accordance with a 125 MHz clock signal (hereinafter referred to as PMA_TX_CLK) received via a TXCMU (Transmit Clock Multiplier Unit). The PISO transmits the converted signal to a PMD (Physical Medium Dependent) layer.

  In the PMD layer, processing for converting an electrical signal into an optical signal is performed. The converted optical signal is transmitted to each client terminal via an MDI (Medium Dependent Interface).

  On the other hand, in the client terminal, the transmitted signal is synchronized (see FIG. 36-9 “Synchronization state diagram” in Non-Patent Document 1). Specifically, the client terminal determines that synchronization is not achieved when synchronization processing using comma data fails three times in succession. At this time, for example, the client terminal raises an alarm and notifies an operator (specifically, a monitoring device or the like) that synchronization is not established. Hereinafter, the state where synchronization is not achieved may be referred to as “LOSS_OF_SYNC” in accordance with the notation described in Non-Patent Document 1 (see FIG. 36-2 in Non-Patent Document 1). The comma data is a bit pattern used for code synchronization.

JP 2001-285323 A (paragraph 0027, FIG. 3) JP 2008-199470 A (paragraphs 0021 to 0025)

IEEE, “Carrier Sense Multiple Access with Collision Detection (CSMA / CD) access method and physical layer specifications”, IEEE Std 802.3, 2008 Part 3, 2008, p. 33-79

  In recent years, Ethernet (registered trademark) is often used as a network standard. For this reason, by connecting the communication device to the network, the opportunity to connect to a device of another company manufactured based on the Ethernet standard increases. Such an environment complicates the responsibility disassembly point of each device.

  Furthermore, an OAM (operations, administration, maintenance) function implemented by a device manufactured based on the Ethernet standard has a looser standard for determining a failure than a transmission device. In addition, since the transmission device and the client terminal are often manufactured by different manufacturers, when the transmission device switches the transmission path section, the connected client terminal side detects a link down. May end up. In such a case, an alarm indicating a link down abnormality is raised from the client terminal side, so that both the user and the device manufacturer have to investigate the cause.

  For example, when GbE path protection (switching) is performed in the Ethernet network, the client terminal detects an instantaneous input interruption. In this case, since the client terminal makes a restart request for autonegotiation (Autonegotiation), the communication state becomes a link-down state as a result. In this state, since an alarm is raised from the client terminal (or end user), for example, the operator has to be aware of what the alarm is. Further, there is a problem that the main signal is not connected until auto-negotiation is established. This also has the same problem in the optical network described in Patent Document 1.

  Therefore, an object of the present invention is to provide a communication apparatus and a path switching method capable of suppressing the occurrence of link down at the time of path switching in the protection configuration of Gigabit Ethernet.

  The communication apparatus according to the present invention includes two signal transmission means connected to each of two lines for transmitting the same transmission signal, switching the transmission path of the transmission signal to each other, and transmitting the transmission signal to another apparatus. Each signal transmission means, based on the ratio of the code included in the transmission signal, based on the line quality of the comma signal generation means for generating a comma signal that is data used for code synchronization, The operating state of one of the signal transmission means is determined to be an active system that is an operating state for transmitting a signal to another device, and the operation state of the other signal transmission means is stopped from transmitting signals to the other device. An operation state determination unit that determines a standby system that is an operation state to be performed, a signal selection unit that selects one of a transmission signal and a comma signal as a signal to be transmitted to another device, and a signal selected by the signal selection unit A clock signal synchronizing means for synchronizing a clock signal used for transmission with a clock signal generated by another signal transmitting means, and a signal selected by the signal selecting means according to the clock signal synchronized by the clock signal synchronizing means A selection signal transmission means for transmitting to another device; and a control information output means for outputting control information based on the operation state determined by the operation state determination means to the signal selection means and the selection signal transmission means. When the control information is received, the transmission signal is selected when the operation state indicated by the control information is the active system, and the comma signal is selected when the operation state is the standby system. When the control information is received, when the operation state indicated by the control information is the active system, the signal selected by the signal selection means is transmitted to another device according to the clock signal, Use state, characterized in that it stops the transmission of the signal when the standby system.

  In the path switching method according to the present invention, two signal transmission means are connected to two lines that transmit the same transmission signal, and two signal transmission units that transmit the transmission signal that transmits the connected line to another device are switched between each other. A path switching method for determining a transmission path of a transmission signal, which generates a comma signal, which is data used for code synchronization, based on a ratio of codes included in the transmission signal, and improves the line quality of a connected line. Based on this, the operational state of one of the signal transmission means is determined as an operational system that is an operational state for transmitting a signal to another device, and the operational state of the other signal transmission means is determined as the signal state to the other device. It is determined that the standby system is in the operating state in which transmission is to be stopped, control information is generated based on the determined operating state, and when the control information is generated, the operating state indicated by the control information is the active system When Select the signal as a signal to be transmitted to another device, select the comma signal as the signal to be transmitted to the other device when the operation state is standby, and select the clock signal used to transmit the selected signal as the other In synchronization with the clock signal generated by the signal transmission means, when the control information is generated, the signal selected when the operation state indicated by the control information is the active system is changed according to the clock signal. It transmits to the apparatus, and when the operation state is a standby system, the transmission of the signal is stopped.

  ADVANTAGE OF THE INVENTION According to this invention, generation | occurrence | production of the link down at the time of path | route switching can be suppressed in the protection structure of Gigabit Ethernet.

It is explanatory drawing which shows the example of the ring network where the communication apparatus by this invention is used. It is a block diagram which shows the example of the communication apparatus in this invention. It is a flowchart which shows the operation example of the communication apparatus in this invention. It is a block diagram which shows the example of the minimum structure of the communication apparatus by this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram showing an example of a ring network in which a communication apparatus according to the present invention is used. The ring network illustrated in FIG. 1 is a network in which paths are duplicated, and a UPSR system is used as a protection system. In the following description, as illustrated in FIG. 1, a case where the network topology is a ring configuration will be described. Specifically, the information from the client terminal input to Node 10 is transmitted in the direction of Node 11 and is transmitted to the client terminal connected to Node 11. In addition, it is assumed that the communication device according to the present invention is applied to Node 11 (more specifically, a portion that outputs information in Node 11).

  FIG. 2 is a block diagram illustrating an example of a communication device according to the present embodiment. The communication apparatus illustrated in FIG. 2 is applied to a physical layer of a LAN (Local Area Network), for example. That is, it can be said that the communication apparatus illustrated in FIG. 2 shows the configuration of the PMA layer peripheral portion that outputs a signal to the client terminal. The communication device in the present embodiment may be implemented as a single device or may be implemented as a part of another device. Further, the left side of the communication apparatus illustrated in FIG. 2 is the network side, and the right side is the client terminal side. The communication device and the client terminal are connected by an optical line such as an optical fiber, for example.

  The communication apparatus according to this embodiment includes two signal transmission units 100 and 110 (hereinafter referred to as a 0 system and a 1 system). The two signal transmission units 100 and 110 are configured to switch the signal transmission path to each other and transmit the received signal to another device. The two signal transmission units 100 and 110 are connected to two lines that transmit the same signal. In the example shown in FIG. 1, the two signal transmission units 100 and 110 are connected to the respective duplexed paths.

  The signal transmission unit 100 (that is, the 0 system) includes a data selection unit 20, a COMMA generation unit 30, a switching determination / control unit 40, a PLL (Phase Locked Loop) 50, a TBI unit 60, and an optical Mod 70. I have. The TBI unit 60 includes a PISO 60a and a TXCMU 60b. Similarly, the signal transmission unit 110 (that is, system 1) includes a data selection unit 21, a COMMA generation unit 31, a switching determination / control unit 41, a PLL 51, a TBI unit 61, and an optical Mod 71. . The TBI unit 61 includes a PISO 61a and a TXCMU 61b. Since the functions of the 0 system and the 1 system are the same, the function of the 0 system will be described below.

  The switching determination / control unit 40 communicates information (hereinafter referred to as channel quality information) indicating the line quality of each connected line with the switching determination / control unit 41 of another system, and determines the operation state. To do. Here, the operation state is either an operation state in which a signal is transmitted to the client device (hereinafter referred to as an active system) or an operation state in which transmission of a signal to the client device is stopped (hereinafter referred to as a standby system). Examples of channel quality information include, for example, signal degradation information (SD: Signal Degrade) indicating whether the bit error rate of a signal has deteriorated below a predetermined threshold, or signal failure information indicating whether transmission has failed. (SF: Signal Fail).

  Specifically, the switching determination / control unit 40 notifies the other system (more specifically, the switching determination / control unit 41) of the line quality of the line connected to the own system. Then, the switching determination / control unit 40 determines the operating state of one of the systems as the active system based on at least one of the line quality of the line connected to the own system and the line quality of the other system. Then, the operation status of the other system is determined as the standby system. Then, the switching determination / control unit 40 outputs control information based on the determined operation state to the data selection unit 20 and the optical Mod 70. By outputting this control information to the data selection unit 20 and the optical Mod 70, the standby system and the active system are switched. For example, the switching determination / control unit 40 may determine that the standby system is set when the communication quality of a signal transmitted through a line connected to the local system falls below a predetermined threshold.

  In addition, the switching determination / control unit 40 determines whether the active system and the standby are based on the communication quality of the signal transmitted through the line connected to the other system as well as the communication quality of the signal transmitted through the line connected to the other system. The operation state of the own system may be determined for any of the systems. For example, when the line quality connected to another system is better than the line quality connected to the own system, the switching determination / control unit 40 may determine the operation state of the own system as the standby system. In this case, the switching determination / control unit 41 of the other system may determine the operation state of its own system based on the operation state determined by the switching determination / control unit 40. Specifically, each switching determination / control unit may determine the 1 system as the active system when the 0 system is determined as the standby system, and the 1 system as the standby system when the 0 system is determined as the active system. Just decide.

  In addition, when the switching determination / control unit 40 notifies the data selection unit 20 and the optical Mod 70 of the control information, the switching time of the optical Mod 70 to start the optical output and the operation time necessary for the optical output to stop are considered. Adjust the control timing. Hereinafter, a control timing adjustment method will be described.

  Assume that the line quality has deteriorated on the ring network side of the 0 system from the operating state where the 0 system is the active system. In this case, the 0-system switching determination / control unit 40 transmits control information based on the operation state (specifically, an instruction to issue comma data) to the data selection unit 20. In addition, the switching determination / control unit 40 transmits control information (specifically, a light output stop instruction) based on the operation state to the light Mod 70 with a delay of a predetermined period. The light Mod 70 described later stops the light output upon receiving this stop instruction. The predetermined period described above is a period in which comma synchronization is performed at least four times in a normal state. This period corresponds to the time required to return from SYNC_ACQUIRED_4 to SYNC_ACQUIRED_1 as a status transition in FIG. 36-9 “Synchronization state diagram” of Non-Patent Document 1.

  On the other hand, the switching determination / control unit 40 instructs the data selection unit 20 to issue comma data, and at the same time notifies the switching determination / control unit 41 that the line quality of the operation system (system 0) has deteriorated. Then, the switching determination / control unit 40 and the switching determination / control unit 41 switch the active system from the 0 system to the 1 system. Specifically, the switching determination / control unit 40 switches the operation state of the 0 system to the standby system, and the switching determination / control unit 41 switches the operation state of the 1 system to the operation system.

  After the operating system is switched from the 0 system to the 1 system, the switching determination / control unit 41 delays by a predetermined period and sends control information (specifically, a light output start instruction) to the optical Mod 71 based on the operating state. Send. In addition, the switching determination / control unit 41 transmits control information (specifically, an instruction to issue tx_code-group <9: 0>) to the data selection unit 21 at the same time as the light output start instruction. . The light Mod 71 starts the light output in response to the emission instruction. Note that the predetermined period described above is a period in which comma synchronization is performed at least four times in a normal state as described above.

  The state of data when the switching process is performed will be further described. Since the line quality is degraded on the 0-system ring network side, first, the data with degraded quality is output from the 0-system. After that, the switching determination / control unit 40 determines that the line is to be switched, and until the optical Mod 70 stops the optical output, comma data is transmitted from the 0 system. On the other hand, from the first system, comma data is transmitted until the data selection unit 21 switches the output data to tx_code-group <9: 0> after the optical Mod 71 starts optical output.

  The output light to the client terminal is a combined light of the output light output from the light Mod 70 and the output light output from the light Mod 71. Therefore, depending on the output switching timing, a state where both the light Mod 70 and the light Mod 71 are emitted, or a state where both the light Mod 70 and the light Mod 71 are not emitted (that is, a state where the output is cut off) occurs. become.

  When the output stop process to the light Mod 70 is slow or the output start process to the light Mod 71 is early, both the light Mod 70 and the light Mod 71 are emitted. In this case, first, from a state where data with degraded quality is output from the 0 system, a state where only the light Mod 70 is emitted by sending comma data. This state corresponds to the state transitioned from SYNC_ACQUIRED_2 to SYNC_ACQUIRED_4 to SYNC_ACQUIRED_1 in FIG. 36-9 “Synchronization state diagram” of Non-Patent Document 1. Thereafter, both the light Mod 70 and the light Mod 71 emit light by sending comma data. Then, after the comma data is transmitted, only the light Mod 71 is emitted, and then tx_code-group <9: 0> is transmitted. Note that the state where both the light Mod 70 and the light Mod 71 emit light is not a preferable state because the light level becomes high. Therefore, it is desirable to suppress this state instantaneously.

  On the other hand, when the output stop process to the light Mod 70 is early or the output start process to the light Mod 71 is late, both the light Mod 70 and the light Mod 71 are not emitted (that is, the output is cut off). In this case, first, from a state where data with degraded quality is output from the 0 system, a state where only the light Mod 70 is emitted by sending comma data. This state also corresponds to the state transitioned from SYNC_ACQUIRED_2 to SYNC_ACQUIRED_4 to SYNC_ACQUIRED_1 in FIG. 36-9 “Synchronization state diagram” of Non-Patent Document 1. Thereafter, after no data is transmitted (that is, the output is cut off), tx_code-group <9: 0> is transmitted via a state in which only optical Mod 71 is emitted by transmitting comma data. It becomes a state.

  From the above, the switching determination / control unit 40 shortens the period during which both the optical Mod 70 and the optical Mod 71 transmit comma data and emits light as much as possible (more preferably, the period is set to 0), and the optical Mod 70 The control information is transmitted so that the output interruption period in which neither the light Mod 71 nor the light Mod 71 emits light is as short as possible. Specifically, the switching determination / control unit 40 (and the switching determination / control unit 41) transmits the control information to the optical Mod 70 (and the optical Mod 71), and then the optical Mod 70 (and the optical Mod 71) operates. Control information is transmitted based on a transmission interval determined according to a response time until the start and an optical Mod 70 (and optical Mod 71) time for performing EO (Electrical-Optical) conversion. In this way, the switching determination / control unit 40 (and the switching determination / control unit 41) shifts the time, and the data selection unit 20 (and the data selection unit 21) and the optical Mod 70 (and the optical Mod 71). Control. Here, the operation performed by the optical Mod 70 (and the optical Mod 71) is an operation of starting optical output or stopping optical output. In addition, the process which optical Mod70 (and optical Mod71) performs is mentioned later.

  In addition, the switching determination / control unit 40 receives its own 125 MHz clock signal from the PLL 50 described later, and notifies the other system switching determination / control unit 41 of the received clock signal. Further, the switching determination / control unit 40 receives the 125 MHz clock signal from the PLL 50 and the other 125 MHz clock signal from the other system switching determination / control unit 41, and sends the clock signal corresponding to the determined operation state to the TBI unit 60. (More specifically, the TXCMU 60b) is notified. At this time, the switching determination / control unit 40 also notifies the PLL 50 of a clock signal corresponding to the determined operation state.

  In the above description, the case where the switching determination / control unit 40 receives the clock signal of the other system and synchronizes the clock signal of the own system has been described. In addition, the switching determination / control unit 40 may pass the own clock signal as a base clock to another system.

  The data selection unit 20 receives a signal (that is, tx_code-group <9: 0>) from the client terminal converted by the PCS layer. Then, the data selection unit 20 detects RD (Running Disparity) information from the received signal (tx_code-group <9: 0>) and passes it to the COMMA generation unit 30. Here, the RD information is a cumulative number difference of “0” or “1” included in the encoded signal.

  The data selection unit 20 receives comma data transmitted from a COMMA generation unit 30 described later. When the data selection unit 20 receives the control information from the switching determination / control unit 40, the data selection unit 20 transmits either the signal transmitted from the PCS layer or the comma data received from the COMMA generation unit 30 to the client terminal. Select whether to do.

  Specifically, the data selection unit 20 selects a signal transmitted from the PCS layer when the operational state indicates the active system, and selects a comma signal when the operational state is the standby system. Then, the data selection unit 20 transmits the selected data to the TBI unit 60 (more specifically, PISO 60a).

  Note that the switching determination / control unit 40 transmits control information to the data selection unit 20 when the line quality deteriorates as switching occurs. For this reason, when the data selection unit 20 recognizes that the line quality of the line connected to its own system has deteriorated enough to cause switching, the data selection unit 20 immediately outputs the comma data from the state in which tx_code-group <9: 0> is output. It can be said that it changes to the state to do.

  The COMMA generator 30 generates comma data based on the ratio of codes included in the received signal. The comma data can also be referred to as a comma signal. Specifically, the COMMA generation unit 30 generates comma data with an appropriate RD based on the RD information received from the data selection unit 20. Then, the COMMA generation unit 30 transmits the generated comma data to the data selection unit 20. For example, the COMMA generation unit 30 determines whether to select “0011111” or “1100000” indicating the comma data based on the RD, and transmits the determined comma data to the data selection unit 20.

  Note that the COMMA generation unit 30 may generate comma data based on the method described in Non-Patent Document 1 (see Non-Patent Document 1 “36.2.4.9 Comma considerations”). Note that the comma data generated based on the above method can be described as “/ COMMA /” in accordance with the description in Non-Patent Document 1. That is, the comma data received by the data selection unit 20 can be described as “tx_code-group <9: 0> = / COMMA /” in accordance with the notation of the signal from the client terminal converted by the PCS layer.

  The PLL 50 generates a 125 MHz clock signal used for GbE data transmission, and transmits the generated clock signal to the switching determination / control unit 40. The PLL 50 synchronizes a clock signal used for data transmission with a clock signal generated in another system. Specifically, the PLL 50 receives a 125 MHz clock signal according to the operation system from the switching determination / control unit 40, and generates a 125 MHz clock signal depending on the received clock and having a phase in both the 0 system and the 1 system. To do. For example, the PLL 50 may compare the phase of the received clock signal with the phase of the currently transmitted clock signal and generate a clock signal delayed according to the phase difference. However, the method by which the PLL 50 generates a 125 MHz clock signal in which the phases of the 0-system and the 1-system match is not limited to the above method. The PLL 50 may use a known method as a method of generating a clock signal by adjusting the phase so that the clock signal is subordinate.

  The TBI unit 60 receives tx_code-group <9: 0> or comma data from the data selection unit 20 and performs parallel-serial conversion based on the clock signal received from the switching determination / control unit 40. Specifically, the PISO 60a converts the parallel data received from the data selection unit 20 into serial data based on the clock signal received from the switching determination / control unit 40 via the TXCMU 60b. Then, the TBI unit 60 notifies the optical serial 70 of the converted serial data. For example, the TBI unit 60 may use the converted serial data (for example, in the form of PMD_UNITDATA.request (serial data)) as a parameter of a processing request (PMD_UNITDATA.request) for the optical Mod 70. The PISO 60a and the TXCMU 60b correspond to the PISO and TXCMU in FIG. 36-10 of Non-Patent Document 1. That is, the TBI unit 60 corresponds to the TBI in FIG. 36-10 of Non-Patent Document 1.

  Note that the TBI unit 60 illustrated in FIG. 2 includes a function for performing a transmission process (more specifically, PISO 60a and TXCMU 60b). However, the TBI unit 60 may include a function for performing a receive process.

  When receiving the processing request (specifically, PMD_UNITDATA.request) for the optical Mod 70 from the TBI unit 60, the optical Mod 70 converts the electrical signal into an optical signal and outputs the converted optical signal to the client terminal. Further, when receiving the control information based on the operation state from the switching determination / control unit 40, the optical Mod 70 switches between the start and stop of the optical output. The light Mod 70 corresponds to “Physical Medium Dependent (PMD)” described in Non-Patent Document 1. The optical Mod 70 is realized by, for example, an electro-optical (EO) modulator that performs optical modulation based on an electric signal.

  From the above, it can be said that the TBI unit 60 and the optical Mod 70 transmit the signal selected by the data selection unit 20 to the client terminal according to the control information from the switching determination / control unit 40. Specifically, when the operation state based on the control information indicates an active system, the TBI unit 60 and the optical Mod 70 transmit data to the client terminal based on the clock signal selected by the switching determination / control unit 40. On the other hand, when the operation state based on the control information indicates a standby system, the optical Mod 70 stops data transmission.

  Next, the operation will be described. FIG. 3 is a flowchart illustrating an operation example of the communication apparatus according to the present embodiment. In the following description, it is assumed that the 0 system is the active system and the 1 system is the standby system in the initial state. In this state, the case where the line quality of the line connected to the 0 system deteriorates and the 1 system is switched to the active system will be described.

  When the communication device receives the signal, the COMMA generator 30 and the COMMA generator 31 generate comma data based on the ratio of codes included in the signal (steps S1 and S2). Here, when the switching determination / control unit 40 detects the degradation of the 0-system channel quality, it notifies the detected signal quality to other signal transmission means (specifically, the signal transmission means 110) (step S3). The operation state of itself is determined (step S4). Here, the switching determination / control unit 40 determines the operating state as the standby system. On the other hand, the switching determination / control unit 41 determines the operating state of the own signal transmission unit when it receives the line quality from another signal transmission unit (specifically, the signal transmission unit 100) (step S5). Here, the switching determination / control unit 41 determines the operating state as the active system. Then, the switching determination / control unit 41 transmits the clock signal generated by the PLL 51 to the signal transmission unit 100 (step S6).

  When the switching determination / control unit 40 determines its own operation state, the switching determination / control unit 40 outputs control information based on the determined operation state (here, standby system) to the data selection unit 20 and the optical Mod 70. At this time, the switching determination / control unit 40 transmits the control information to the optical Mod 70 after a predetermined time has elapsed after transmitting the control information to the data selection unit 20 (step S7) (step S8). When receiving the control information, the data selection unit 20 selects either the received signal or the comma data as the data to be transmitted (step S9). In this case, the data selection unit 20 selects comma data.

  Similarly, when the switching determination / control unit 41 determines its own operation state, it outputs control information based on the determined operation state (in this case, the operation system) to the data selection unit 21 and the optical Mod 71. At this time, the switching determination / control unit 41 transmits control information to the data selection unit 21 (step S10), and then transmits control information to the optical Mod 71 after a predetermined time has elapsed (step S11). Upon receiving the control information, the data selection unit 21 selects either the received signal or comma data as data to be transmitted (step S12). In this case, the data selection unit 21 selects the received signal.

  When the switching determination / control unit 40 receives the clock signal generated by the PLL 51 from the switching determination / control unit 41, the switching determination / control unit 40 transmits the received clock signal to the PLL 50 (step S13). The PLL 50 generates a clock signal so as to be synchronized with the received clock signal (step S14).

  The TBI unit 60 transmits comma data to the optical Mod 70 in accordance with the clock signal synchronized by the PLL 50 (step S15). And optical Mod70 will stop transmission of comma data, if control information is received (Step S16). Note that the optical Mod 70 is in either a state in which comma data is transmitted or a state in which a signal is interrupted, depending on the timing at which control information is received.

  On the other hand, the TBI unit 61 transmits the received data to the optical Mod 71 according to its own clock signal (step S17). And optical Mod71 will start transmission of the received data, if control information is received (step S18).

  As described above, according to the present embodiment, the COMMA generator 30 generates comma data based on the ratio of codes included in a signal. Further, the switching determination / control unit 40 determines the operation state of one of the systems as the active system and the operation state of the other system as the standby system based on the line quality. Then, the switching determination / control unit 40 outputs control information based on the determined operation state to the data selection unit 20 and the optical Mod 70. The data selection unit 20 selects a received signal when the operation state indicated by the control information is the active system, and selects comma data when the operation state is the standby system. The PLL 50 synchronizes the clock signal used for transmitting the selected signal with the clock signal generated by another system (system 1). Then, when the operation state indicated by the control information is the active system, the TBI unit 60 and the optical Mod 70 transmit the signal selected by the data selection unit 20 to the client terminal according to the synchronized clock signal. On the other hand, when the operation state is the standby system, the TBI unit 60 and the optical Mod 70 stop transmitting the selected signal. By performing the above processing in the gigabit Ethernet protection configuration, the occurrence of link down at the time of path switching can be suppressed.

  That is, according to the present embodiment, when the switching determination / control unit 40 switches between the active system and the standby system, the clock signal (specifically, PMA_TX_CLK) output to the 0 system and the 1 system is synchronized, and The TBI unit 60 and the optical Mod 70 send the comma data that is explicitly synchronized to the client terminal. Therefore, the client terminal side can suppress transition to LOSS_OF_SYNC indicating a state where synchronization is not achieved. For example, according to the present embodiment, in FIG. 36-9 “Synchronization state diagram” of Non-Patent Document 1, the synchronization state transitions to LOSS_OF_SYNC (specifically, three consecutive times based on comma data) Synchronization) can be avoided. Therefore, it can be avoided that the client terminal detects a link down at the time of switching in the above-described protection method.

  In the synchronization mechanism in 1000BASE-X, a 10-bit code group (code-group) × 2 (that is, a total of 20 bits) is expressed in the format of “comma data + Valid data”, and this data is invalidated. Comma synchronization is performed by receiving before entering the (Invalid) state. The reference clock in 1000BASE-X is 125 MHz, and the communication apparatus performs 10-bit parallel processing for both reception processing and transmission processing. Here, if the phases of the clock signals are not matched, the communication apparatus performs parallel processing from the middle bit of the 10-bit data, and thus cannot correctly recognize the comma pattern. Although resynchronization is performed every time several tens of bits are received, a state where synchronization cannot be achieved occurs at least once. However, according to the present embodiment, the loss of comma data can be suppressed by phase matching at the time of switching by adding a mechanism for matching the phases of the clock signals of the 0-system and the 1-system in the protection configuration.

  In the communication apparatus according to the present embodiment, the operation time (specifically, the data selection unit) until one switching determination / control unit stops the light output and the other switching determination / control unit starts the light output. 20 and the timing at which the control instruction is given to the optical Mod 70) can be taken into consideration, so that the instantaneous interruption time generated by switching can be minimized. In addition, it is a requirement that the client terminal becomes out of synchronization (LOSS_OF_SYNC) by sending comma data during a period when the line quality is degraded and the data contents are indefinite. The number of comma data synchronization errors can be minimized.

  Next, a modification of the communication device according to this embodiment will be described. Each signal transmission means 100, 110 may synchronize both the 0-system and 1-system transmission data at the data level so as not to send indefinite data when a failure occurs.

  Specifically, when the data selection unit 20 receives tx_code-group <9: 0> from the PCS layer, the data selection unit 20 transmits the received information to another system (that is, the switching determination / control unit 41) via the switching determination / control unit 40. ). Similarly, when receiving the tx_code-group <9: 0> from the PCS layer, the data selection unit 21 passes the received information to the other system (that is, the switching determination / control unit 40) via the switching determination / control unit 41. Send.

  When the switching determination / control unit 40 and the switching determination / control unit 41 receive information from another system, the received data is stored in a data buffer (not shown). The data stored in the buffer is continuous data of tx_code-group <9: 0> received by the 0-system and the 1-system.

  The switching determination / control unit 40 and the switching determination / control unit 41 synchronize both transmission data at the data level. By synchronizing in this way, the same data is transmitted for both the 0-system and the 1-system, so that the connected data string can be transmitted even when the switching occurs, so that it is possible to realize uninterrupted switching.

  In order to realize the above-described uninterruptible switching, a predetermined data buffer may be prepared so as not to send indefinite data when a failure occurs. Specifically, the switching determination / control unit 40 determines the operating state, generates a trigger for switching the operating state, and then takes a data buffer for the time taken to complete the switching process, and the 0 system and 1 A data buffer that absorbs a delay difference (specifically, propagation delay, processing delay, etc.) due to the path length of the system.

  Next, an example of the minimum configuration of the communication apparatus according to the present invention will be described. FIG. 4 is a block diagram showing an example of the minimum configuration of the communication apparatus according to the present invention. The communication apparatus according to the present invention is connected to each of two lines that transmit the same transmission signal, switches the transmission path of the transmission signal to each other, and transmits the transmission signal to another apparatus (for example, a client terminal). Two signal transmission means 80 and 90 (for example, signal transmission means 100 and 110) are provided.

  Each signal transmission means 80, 90 generates a comma signal (for example, comma data) that is data used for code synchronization based on the ratio (for example, RD) of the code included in the transmission signal. (For example, the COMMA generation units 30 and 31) and the line quality (for example, signal deterioration information, signal failure information) of the connected line, the operating state of one of the signal transmission means is set to the other device. The operating state determining unit 82 (determining the operating state in which the signal is transmitted and determining the operating state of the other signal transmission means as the standby system in the operating state in which the transmission of signals to other devices is stopped. For example, the switching determination / control units 40 and 41) and signal selection means 83 (for example, the data selection unit 20) that selects one of the transmission signal and the comma signal as a signal to be transmitted to another device. 21), a clock signal synchronization unit 84 (for example, PLL 50, 51) for synchronizing a clock signal used for transmission of the signal selected by the signal selection unit 83 with a clock signal generated by another signal transmission unit, and signal selection Selection signal transmission means 85 (for example, TBI units 60 and 61, optical Mod 70 and 71) for transmitting the signal selected by the means 83 to another device in accordance with the clock signal synchronized by the clock signal synchronization means 84, and operation Control information output means 86 for outputting control information based on the operation state determined by the state determination means 82 to the signal selection means 83 and the selection signal transmission means 85 is included.

  When the control information is received, the signal selection unit 83 selects the transmission signal when the operation state indicated by the control information is the active system, and selects the comma signal when the operation state is the standby system. In addition, when the control information is received, the selection signal transmission unit 85 transmits the signal selected by the signal selection unit 83 to another device according to the clock signal when the operation state indicated by the control information is the active system. When the operating state is the standby system, the signal transmission is stopped.

  With such a configuration, the occurrence of link down at the time of path switching can be suppressed in the protection configuration of Gigabit Ethernet. That is, in the present invention, by providing a mechanism on the communication device (transmission device) side that prevents the client terminal from raising an unnecessary alarm by switching the transmission path section by the communication device, occurrence of link down at the time of route switching. Is suppressed.

  Specifically, after the control information output unit 86 outputs the control information to the signal selection unit 83, the selection signal transmission unit is delayed by a predetermined period (for example, a period in which comma synchronization is performed at least four times in a normal state). The control information is transmitted to 85.

  The selection signal transmission unit 85 converts the transmission signal from an electric signal to an optical signal, and the control information output unit 86 outputs the control information to the signal selection unit 83, and then the selection signal transmission unit 85 converts the transmission signal into an optical signal. The control information is output to the selection signal transmission means 85 at intervals determined based on the processing time for conversion to a signal (for example, response time until the optical Mod 70 starts operation, time for performing EO conversion, etc.). May be.

  Further, when the operation state determination means 82 notifies the other signal transmission means of the line quality of the connected line and receives the line quality from the other signal transmission means, the operation state determination means 82 determines the operation state in the own signal transmission means. Also good.

  Further, the clock signal synchronization means 84 may synchronize the clock signal used for transmission of the signal selected by the signal selection means 83 with the clock signal generated by the signal transmission means whose operation state is the standby system.

  The present invention is preferably applied to a communication device and a communication device connected to a ring network.

10,11 Node
20, 21 Data selection unit 30, 31 COMMA generation unit 40, 41 Switching determination / control unit 50, 51 PLL
60, 61 TBI part 60a, 61a PISO
60b, 61b TXCMU
70, 71 Light Mod
100, 110 Signal transmission means

Claims (7)

Connected to each of two lines that transmit the same transmission signal, comprising two signal transmission means for switching the transmission path of the transmission signal to each other and transmitting the transmission signal to another device;
Each of the signal transmission means is
Comma signal generating means for generating a comma signal, which is data used for code synchronization, based on a ratio of codes included in the transmission signal;
Based on the line quality of the connected line, the operating state of any one of the signal transmission means is determined to be an operating system that is an operating state for transmitting a signal to another device, and the operating state of the other signal transmission means is determined. , An operating state determination means for determining a standby system that is in an operating state to stop transmission of signals to other devices,
A signal selection means for selecting one of the transmission signal and the comma signal as a signal to be transmitted to another device;
A clock signal synchronization means for synchronizing a clock signal used for transmission of the signal selected by the signal selection means with a clock signal generated by another signal transmission means;
A selection signal transmission means for transmitting the signal selected by the signal selection means to another device in accordance with the clock signal synchronized by the clock signal synchronization means;
Control information based on the operation state determined by the operation state determination means, and control information output means for outputting to the signal selection means and the selection signal transmission means,
The signal selection means, when receiving the control information, selects the transmission signal when the operation state indicated by the control information is an active system, and selects the comma signal when the operation state is a standby system. Selected,
When the control signal is received, the selection signal transmission unit transmits the signal selected by the signal selection unit to another device according to the clock signal when the operation state indicated by the control information is an active system. And the transmission of the signal is stopped when the operation state is a standby system. The communication apparatus according to claim 1, wherein the control information output means transmits the control information to the selection signal transmission means after outputting the control information to the signal selection means, after a predetermined period of delay. The selection signal transmission means converts the transmission signal from an electrical signal to an optical signal,
The control information output means outputs the control information to the selection signal transmission means at an interval determined based on the processing time for the selection signal transmission means to convert the transmission signal into an optical signal after outputting the control information to the signal selection means. The communication device according to claim 1, wherein the communication device outputs the communication device. The operation state determining means notifies the line quality of the connected line to other signal transmission means, and determines the operation state in the own signal transmission means when receiving the line quality from the other signal transmission means. The communication device according to claim 3. The clock signal synchronization means synchronizes the clock signal used for transmission of the signal selected by the signal selection means with the clock signal generated by the signal transmission means whose operation state is the standby system. The communication apparatus of any one of Claims. Two signal transmission means connected to each of two lines transmitting the same transmission signal and transmitting the transmission signal transmitting the connected line to another device are switched to each other, and the transmission path of the transmission signal is changed. A route switching method to be determined,
Based on the ratio of codes included in the transmission signal, a comma signal that is data used for code synchronization is generated,
Based on the line quality of the connected line, the operating state of any one of the signal transmission means is determined to be an operating system that is an operating state for transmitting a signal to another device, and the operating state of the other signal transmission means is determined. , Determine the standby system that is in an operational state to stop transmission of signals to other devices,
Generating control information based on the determined operational state;
When the control information is generated, when the operation state indicated by the control information is the active system, the transmission signal is selected as a signal to be transmitted to another device, and the operation state is the standby system Selecting the comma signal as a signal to be transmitted to another device,
Synchronize the clock signal used to transmit the selected signal with the clock signal generated by other signal transmission means,
In response to the generation of the control information, when the operation state indicated by the control information is the active system, the selected signal is transmitted to another device according to the clock signal, and the operation state is the standby system. The route switching method characterized by stopping the transmission of the signal when The process of selecting a transmission signal or a comma signal as a signal to be transmitted to another device, and then performing a transmission process of the selected signal or a stop process of the selected signal after delaying a predetermined period. 6. The route switching method according to 6.

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