JP5929348B2 - SDH transmission system - Google Patents

Description

  The present invention relates to an SDH (Synchronous Digital Hierarchy) transmission system.

  Conventionally, an SDH transmission method is known as a transmission method used for an Internet backbone line or the like. SDH is a standard standardized by ITU-T (International Telecommunication Union-Telecommunication standard sector).

  In an SDH transmission system, normally, in order to cope with a failure in a transmission path, two opposing SDH transmission apparatuses are redundantly connected by two transmission paths of an active system and a standby system (1 + 1 redundant configuration). When a failure occurs in the active transmission line, the line is switched to the standby transmission line, and the SDH frame is transmitted. In the SDH transmission system, line switching from the active system to the standby system is performed using K1 / K2 bytes included in a section overhead (SOH) of the SDH frame (see, for example, Patent Document 1).

JP-A-8-149101

  FIG. 1 shows a configuration of a general SDH transmission system. An SDH transmission system 100 shown in FIG. 1 includes SDH backbone transmission apparatuses 101 and 102 that form a backbone line, and SDH transmission terminal apparatuses 103 and 104 that terminate services and the like. In the SDH transmission system 100 shown in FIG. 1, the SDH backbone transmission devices 101 and 102 are backbone transmission devices with a transmission rate of 2.5G. In the SDH transmission system 100, the SDH backbone transmission device 101 is connected to the SDH transmission terminal device 103, and the SDH backbone transmission device 102 is connected to the SDH transmission terminal device 104. The SDH transmission terminal station device 103 and the SDH backbone transmission device 101, and the SDH transmission terminal device 104 and the SDH backbone transmission device 102 are redundantly connected by transmission lines such as transmission speeds of 50M and 150M ( 1 + 1 redundant configuration).

  In the SDH transmission system 100 as shown in FIG. 1, when traffic increases and a transmission path with a larger capacity becomes necessary, or when the SDH backbone transmission apparatuses 101 and 102 become obsolete, the SDH backbone transmission apparatuses 101 and 102 A work (also referred to as “accommodation change work”) is performed to replace the stool with a new device. FIG. 1 illustrates an example in which SDH backbone transmission apparatuses 101 and 102 with a transmission rate of 2.5 G are replaced with SDH transmission terminal apparatuses 105 and 106 with a transmission rate of 10 G.

  When switching to the new SDH backbone transmission device as described above, it is desirable to minimize the influence on the service being provided (line interruption or line interruption). As described above, the transmission path between the SDH transmission terminal station device and the SDH backbone transmission device has a 1 + 1 redundant configuration, but the accommodation changing operation of such redundantly connected devices is a very complicated work procedure. Is required. In SDH, a 1 + 1 redundant configuration switching method (sequence with an opposing device) is standardized, but a function corresponding to accommodation change is not defined. Due to the complexity of the procedure of the accommodation changing work, the work time becomes long and the work cost increases, and there is a risk that work mistakes are likely to occur.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a technique capable of simplifying the accommodation changing operation in the SDH transmission system.

  In order to solve the above problems, an SDH transmission system according to an aspect of the present invention includes a first SDH transmission device, a second SDH transmission device, a third SDH transmission device, a first SDH transmission device, a second SDH transmission device, and a third SDH transmission. And a control device for controlling the device. When changing from the state in which the first SDH transmission device and the second SDH transmission device are connected in the 1 + 1 redundancy configuration to the state in which the first SDH transmission device and the second SDH transmission device are connected in the 1 + 1 redundancy configuration, the control device The 1SDH transmission apparatus is set to the first accommodation change mode, the second SDH transmission apparatus is set to the second accommodation change mode, and the third SDH transmission apparatus is set to the third accommodation change mode. When the first SDH transmission apparatus receives an accommodation change start instruction from the control apparatus, a control signal is communicated between the first SDH transmission apparatus, the second SDH transmission apparatus, and the third SDH transmission apparatus to switch a plurality of lines. Is performed.

  The line switching process may include a line switching process from the 0 system to the 1 system and a line switching process from the 1 system to the 0 system.

  The control signal may be transmitted using the K1 / K2 bytes of the section overhead of the SDH frame.

  It should be noted that any combination of the above-described constituent elements and a representation of the present invention converted between an apparatus, a method, a system, a program, a recording medium storing the program, and the like are also effective as an aspect of the present invention.

  According to the present invention, accommodation change work can be simplified in the SDH transmission system.

It is a figure which shows the structure of a general SDH transmission system. It is a figure for demonstrating the SDH transmission system which concerns on embodiment of this invention. It is a figure for demonstrating the bit allocation of the K1 / K2 byte standardized in SDH. It is a figure for demonstrating the procedure of the conventional accommodation change work. It is a figure for demonstrating the structure of the SDH transmission apparatus which concerns on this embodiment. It is a flowchart for demonstrating the accommodation change operation | work which concerns on embodiment of this invention. It is a flowchart for demonstrating operation | movement of the 1st SDH transmission apparatus set to the 1st accommodation change mode. It is a flowchart for demonstrating operation | movement of the 2nd SDH transmission apparatus set to the 2nd accommodation change mode. It is a flowchart for demonstrating operation | movement of the 3rd SDH transmission apparatus set to the 3rd accommodation change mode. It is a figure for demonstrating the procedure of the accommodation change work in the SDH transmission system which concerns on this embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 2 is a diagram for explaining the SDH transmission system according to the embodiment of the present invention. As shown in FIG. 2, in the SDH transmission system 10, the first SDH transmission device 11 and the second SDH transmission device 12 include the 0-system optical fiber 14 that constitutes the 0-system transmission path and the 1-system transmission path. The optical fiber 15 is redundantly connected. Here, the accommodation change which replaces the 2nd SDH transmission apparatus 12 of the transmission speed 2.5G with the 3rd SDH transmission apparatus 13 of the transmission speed 10G is considered.

  First, before explaining the accommodation changing work according to the embodiment of the present invention, the conventional accommodation changing work will be explained. The accommodation change work has been conventionally performed by using a standardized SDH 1 + 1 redundant configuration switching method. The switching of the 1 + 1 redundant configuration is performed using the K1 / K2 bytes in the section overhead (SOH) of the SDH frame. In the accommodation changing operation, the K1 / K2 bytes are given to the first SDH transmission device 11, the second SDH transmission device 12, and the third SDH transmission device 13 by the control device (OPS) 16.

  FIG. 3 is a diagram for explaining bit allocation of K1 / K2 bytes standardized in SDH. As shown in FIG. 3, each of the K1 / K2 bytes is composed of bit strings b1 to b8. In the K1 byte, the bit string from b1 to b4 indicates the type of switching request, and the bit string from b5 to b8 indicates the number of the working transmission line that issued the switching request. In the K2 byte, the bit string from b1 to b4 indicates the number of the transmission line used as the working transmission line, b5 indicates the setting of the switching configuration, and the bit string from b6 to b8 indicates the state of the transmission line. .

  The definition of b1 to b4 of the K1 byte standardized in SDH will be described. When b1 to b4 of the K1 byte are “1110”, it indicates forced switching (FS). The content is to switch the active traffic to the standby system by external control when the standby system is normal. When b1 to b4 of the K1 byte are “1100”, this indicates an automatic switching-transmission path failure (SF: Siganal Fail). The contents are to automatically switch the working traffic to the standby system when detecting a loss of light (LOS) or the like when the standby system is normal. When b1 to b4 of the K1 byte are “1010”, this indicates automatic switching-quality degradation (SD: Signal Degrade). The contents are that the active system traffic is automatically switched to the backup system when the error rate deterioration is detected when the backup system is normal. When b1 to b4 of the K1 byte are “0110”, this represents a wait for restore (WR). The content is that the transmission path name is not changed during the recovery standby protection time after the failure recovery. When b1 to b4 of the K1 byte are “0010”, this indicates a switching response (RR: Reverse Request). The content is to notify the opposing device that the switching has been executed in response to the switching request from the opposing device side. When b1 to b4 of the K1 byte are “0000”, it indicates that there is no switching (NB: No Bridge Required). The content is that there is no switching request from the active system.

  Next, the definition of b1 to b8 of the K1 byte standardized in SDH will be described. When b5 to b8 of the K1 byte are “0010”, it indicates that the 1 system is making a switching request. When b5 to b8 of the K1 byte are “0001”, this indicates that the 0 system is making a switching request. When b5 to b8 of the K1 byte are “0000”, this indicates that no switching request is made (that is, NB).

  Next, the definition of b2 to b4 of the K2 byte standardized in SDH will be described. When b1 to b4 of the K2 byte are “0010”, it indicates that the 1 system is the active system (1 system active), and when it is “0001”, the 0 system is the active system (0 system active). ing.

  Next, the definition of b2 of K2 byte standardized in SDH will be described. When b5 of the K2 byte is “0”, it indicates 1 + 1 redundancy switching.

  Next, the definition of b2 to b8 of the K2 byte standardized in SDH will be described. When b6 to b8 of the K2 byte are “111”, it indicates that the state of the transmission path is MS-AIS (Multiplex Section Alarm Indication Signal). When b6 to b8 of the K2 byte are “110”, this indicates that the state of the transmission path is MS-RDI (Multiplex Section Remote Defect Indication). When b5 to b8 of the K2 byte are “000”, this indicates that the transmission path is in a normal state.

  FIG. 4 is a diagram for explaining the procedure of the conventional accommodation change work. As an initial state, it is assumed that the first SDH transmission device 11 and the second SDH transmission device 12 are redundantly connected by a 0-system optical fiber 14 and a 1-system optical fiber 15, and the 0-system optical fiber 14 is an active system. Operation control of the first SDH transmission apparatus 11, the second SDH transmission apparatus 12, and the third SDH transmission apparatus 13 is performed by transmitting an SDH frame including K1 / K2 bytes from the control apparatus (OPS).

  First, as the procedure (1), the third SDH transmission device 13 performs folding of the low-speed side optical fiber. This work is performed by the worker.

  Next, as a procedure (2), the operator operates the control device 16 to perform forced switching control (FS) to the first system for the third SDH transmission device 13.

  Next, as a procedure (3), the operator operates the control device 16 to perform LockOut control on the first SDH transmission device 11 and the second SDH transmission device 12. Thereby, automatic system switching in the first SDH transmission apparatus 11 and the second SDH transmission apparatus 12 is prevented.

  Next, as procedure (4), the connection of the 1-system optical fiber 15 is changed from the second SDH transmission device 12 to the third SDH transmission device 13. This work is performed by the worker.

  Next, as a procedure (5), the operator operates the control device 16 to perform the LockOut cancellation control on the first SDH transmission device 11. Thereby, the first SDH transmission apparatus 11 is switched from the 0 system to the 1 system.

  Next, as procedure (6), the operator operates the control device 16 to perform LockOut control on the first SDH transmission device 11. As a result, automatic system switching in the first SDH transmission apparatus 11 is prevented.

  Next, as procedure (7), the connection of the 0-system optical fiber 14 is changed from the second SDH transmission device 12 to the third SDH transmission device 13. This work is performed by the worker.

  Next, as a procedure (8), the operator operates the control device 16 to perform the LockOut cancellation control for the first SDH transmission device 11. Also, forced switching cancellation control is performed on the third SDH transmission apparatus 13.

  Finally, as the procedure (9), the operator operates the control device 16 to perform the forced switching control to the 0 system for the first SDH transmission device 11. As a result, an SDH frame including K1 / K2 bytes instructing forced switching to the 0 system is transmitted from the first SDH transmission apparatus 11 to the third SDH transmission apparatus 13, and the third SDH transmission apparatus 13 is forcibly switched to the 0 system. The

  In the above, the accommodation changing work using the K1 / K2 bytes standardized in SDH has been described. As described above, in the conventional accommodation change work, the work of changing the optical fiber connection by the operator and the operation of the control device 16 are complicated, and it takes a lot of time and there is a concern that an operation error may occur. .

  Therefore, in the SDH transmission system 10 according to the present embodiment, a function (accommodation change mode) corresponding to accommodation change is incorporated in each of the first SDH transmission apparatus 11, the second SDH transmission apparatus 12, and the third SDH transmission apparatus 13. . Before the accommodation change operation, the accommodation change mode is set for the first SDH transmission apparatuses 11 and 2 and the third SDH transmission apparatus 13. As a result, the operation of the control device (OPS) in the conventional accommodation change operation described above is automatically performed by the device, and the work of the operator can be greatly reduced. Moreover, the occurrence of work mistakes can be suppressed by reducing the work of the operator.

  FIG. 5 is a diagram for explaining the configuration of the SDH transmission apparatus 18 according to the present embodiment. The SDH transmission device 18 corresponds to the first SDH transmission device 11, the second SDH transmission device 12, and the third SDH transmission device 13 in FIG. Here, of the functional blocks of the SDH transmission apparatus 18, only functional blocks related to accommodation change are shown. Each block shown in the block diagram of the present specification can be realized in terms of hardware by an element such as a CPU of a computer or a mechanical device, and in terms of software, it can be realized by a computer program or the like. The functional block realized by those cooperation is drawn. Therefore, those skilled in the art will understand that these functional blocks can be realized in various forms by a combination of hardware and software.

  As shown in FIG. 5, the SDH transmission apparatus 18 includes a 0-system interface (IF) card 21, a 1-system interface (IF) card 22, and a CPU system that controls switching between the 0-system interface card 21 and the 1-system interface card 22. Package 20. The 0-system interface card 21 and the 1-system interface card 22 are connected to the IF card of the opposing SDH transmission apparatus using an optical fiber.

  As shown in FIG. 5, the CPU package 20 has an SDH switching process program. The SDH switching processing program includes a program that executes a normal switching function and a program that sets one of the first accommodation change mode, the second accommodation change mode, and the third accommodation change mode.

  The normal switching function is a switching function standardized in SDH as described above. On the other hand, a program for setting one of the first accommodation change mode, the second accommodation change mode, and the third accommodation change mode is a program newly incorporated in the SDH transmission system 10 according to the present embodiment. When the accommodation change work is started, the first SDH transmission device 11 is set to one of the first to third accommodation change modes in accordance with an instruction from the control device (OPS) 16. The first accommodation change mode is a mode set in the SDH transmission apparatus at the position of the first SDH transmission apparatus 11 in FIG. In addition, the second accommodation change mode is a mode in which the SDH transmission apparatus at the position of the second SDH transmission apparatus 12 in FIG. 2, that is, the SDH transmission apparatus that is disconnected due to the accommodation change is set. Further, the third accommodation change mode is a mode that is set to the SDH transmission apparatus at the position of the third SDH transmission apparatus 13 in FIG. 2, that is, the SDH transmission apparatus newly connected by the accommodation change.

  FIG. 6 is a flowchart for explaining accommodation changing work according to the embodiment of the present invention. The SDH transmission device 18 starts a switching operation in response to a switching instruction from the control device (OPS) 16. When receiving the switching instruction from the control device 16, the control device 16 determines whether the switching is in the normal mode or the switching using the accommodation change mode (S10). When the instruction from the control device 16 is the normal mode, the CPU system package 20 of the SDH transmission device 18 performs the existing switching operation (S12). The existing switching operation is an accommodation switching operation using the switching function for K1 / K2 bytes standardized in the above-described SDH.

  When the instruction from the control device 16 is a switching instruction using the accommodation change mode, the CPU system package 20 of the SDH transmission device 18 determines the type of mode notified from the control device 16 (S11). When the first accommodation change mode is instructed from the control device 16, the CPU system package 20 changes the operation mode to the first accommodation change mode included in the SDH switching processing program (S13). When the second accommodation change mode is instructed from the control device 16, the CPU system package 20 changes the operation mode to the second accommodation change mode included in the SDH switching processing program (S14). When the third accommodation change mode is instructed from the control device 16, the CPU system package 20 changes the operation mode to the third accommodation change mode included in the SDH switching processing program (S15). When operating in the first to third accommodation change modes, communication between the control device 16 and the SDH transmission device 18 is performed using the K1 / K2 bytes of the SDH frame. That is, when operating in the first to third accommodation change modes, the usage method of the K1 / K2 bytes of the SDH frame is switched from the standardized normal usage method.

  FIG. 7 is a flowchart for explaining the operation of the first SDH transmission apparatus 11 set in the first accommodation change mode. In the accommodation change work, the first SDH transmission device 11, the second SDH transmission device 12, and the third SDH transmission device 13 shown in FIG. Is changed from the second SDH transmission device 12 to the third SDH transmission device 13. The connection change of the 1-system optical fiber 15 is performed by an operator. At this time, the 0-system interface card of the first SDH transmission apparatus 11 and the 0-system interface card of the second SDH transmission apparatus 12 are connected by the 0-system optical fiber 14, and the 1-system interface card of the first SDH transmission apparatus 11 and the third SDH transmission apparatus are connected. 13 1-system interface cards are connected by the 1-system optical fiber 15.

  The CPU system package of the first SDH transmission apparatus 11 set to the first accommodation change mode determines whether or not the “accommodation change step 1 start” command is received from the control device (OPS) 16 (S20). If it has not been received yet, it waits for reception of a command (N in S20). If a command is received (Y in S20), the process proceeds to S21.

  Next, the CPU system package of the first SDH transmission apparatus 11 transmits a “step 1 start” command to the second SDH transmission apparatus 12 set to the second accommodation change mode (S21).

  As will be described later, when receiving the “step 1 start” command, the second SDH transmission apparatus 12 set in the second accommodation change mode returns a “step 1 ok” command. The CPU package of the first SDH transmission apparatus 11 determines whether or not the “step 1 ok” command has been received from the second SDH transmission apparatus 12 (S22), and waits until it is received (N in S22). When the “step 1 ok” command is received from the second SDH transmission apparatus 12 (Y in S22), the process proceeds to S23.

  In S <b> 23, the CPU system package of the first SDH transmission apparatus 11 transmits a “step 1 start” command to the third SDH transmission apparatus 13.

  As will be described later, when receiving the “step 1 start” command, the third SDH transmission apparatus 13 returns the “step 1 ok” command. The CPU package of the first SDH transmission apparatus 11 determines whether or not the “step 1 ok” command is received from the third SDH transmission apparatus 13 (S24), and waits until it is received (N in S24). When the “step 1 ok” command is received from the third SDH transmission apparatus 13 (Y in S24), the process proceeds to S25.

  When the “step 1 ok” command is received from the second SDH transmission apparatus 12 and the third SDH transmission apparatus 13, the first SDH transmission apparatus 11 switches the line from the 0 system to the 1 system (S25).

  Here, the connection destination of the 0-system optical fiber 14 is changed from the second SDH transmission device 12 to the third SDH transmission device 13 by the operator. At this time, the 0-system interface card of the first SDH transmission apparatus 11 and the 0-system interface card of the third SDH transmission apparatus 13 are connected by the 0-system optical fiber 14, and the 1-system interface card of the first SDH transmission apparatus 11 and the third SDH transmission apparatus are connected. 13 1-system interface cards are connected by the 1-system optical fiber 15.

  Thereafter, the CPU system package of the first SDH transmission apparatus 11 determines whether or not the “accommodation change step 2 start” command is received from the control apparatus (OPS) 16 (S26), and waits until it is received (N of S26). . When the command “accommodation change step 2 start” is received from the control device 16 (Y in S26), the process proceeds to S27.

  In S <b> 27, the CPU system package of the first SDH transmission apparatus 11 transmits a “step 2 start” command to the third SDH transmission apparatus 13.

  As will be described later, when receiving the “step 2 start” command, the third SDH transmission apparatus 13 returns the “step 2 ok” command. The CPU package of the first SDH transmission apparatus 11 determines whether or not the “step 2 ok” command is received from the third SDH transmission apparatus 13 (S28), and waits until it is received (N in S28).

  When the “step 2 ok” command is received from the third SDH transmission apparatus 13 (Y in S28), the first SDH transmission apparatus 11 switches the line from the 1-system to the 0-system (S29). The accommodation changing operation of the first SDH transmission apparatus 11 is thus completed.

  FIG. 8 is a flowchart for explaining the operation of the second SDH transmission apparatus 12 set in the second accommodation change mode. The CPU system package of the second SDH transmission apparatus 12 set in the second accommodation change mode first determines whether or not a “step 1 start” command has been received from the first SDH transmission apparatus 11 (S30), and waits until it is received. (N in S30). At this time, the 0-system interface card of the second SDH transmission apparatus 12 and the 0-system interface card of the first SDH transmission apparatus 11 are connected by the 0-system optical fiber 14, and the 1-system interface card of the second SDH transmission apparatus 12 is optically connected. The fiber is not connected.

  When the “step 1 start” command is received from the first SDH transmission apparatus 11 (Y in S30), the CPU system package of the second SDH transmission apparatus 12 controls the 1-system interface card to the LockOut state (S31).

  Thereafter, the CPU system package of the second SDH transmission apparatus 12 transmits a “step 1 ok” command to the first SDH transmission apparatus 11 (S32). The accommodation changing operation of the second SDH transmission apparatus 12 is thus completed.

  FIG. 9 is a flowchart for explaining the operation of the third SDH transmission apparatus 13 set in the third accommodation change mode. The CPU system package of the third SDH transmission apparatus 13 set in the third accommodation change mode first determines whether or not a “step 1 start” command has been received from the first SDH transmission apparatus 11 (S40), and waits until it is received. (N in S40). At this time, the 1-system interface card of the third SDH transmission apparatus 13 and the 1-system interface card of the first SDH transmission apparatus 11 are connected by the 1-system optical fiber 15, and the 0-system interface card of the third SDH transmission apparatus 13 is connected to the optical system card. The fiber is not connected.

  When the “step 1 start” command is received from the first SDH transmission apparatus 11 (Y in S40), the CPU system package of the third SDH transmission apparatus 13 switches the line from the 0 system to the 1 system (S41). Thereafter, the CPU system package of the third SDH transmission apparatus 13 transmits a “step 1 ok” command to the first SDH transmission apparatus 11.

  As described in the explanation of the operation flow of the first SDH transmission apparatus 11 in FIG. 7, when the “step 1 ok” command is transmitted from the third SDH transmission apparatus 13 to the first SDH transmission apparatus 11, the operator performs 0-system light. The connection destination of the fiber 14 is changed from the second SDH transmission device 12 to the third SDH transmission device 13. At this time, the 0-system interface card of the third SDH transmission apparatus 13 and the 0-system interface card of the first SDH transmission apparatus 11 are connected by the 0-system optical fiber 14, and the 1-system interface card of the third SDH transmission apparatus 13 and the first SDH transmission apparatus are connected. 11 1-system interface cards are connected by the 1-system optical fiber 15.

  Thereafter, the CPU package of the third SDH transmission apparatus 13 determines whether or not the “step 2 start” command is received from the first SDH transmission apparatus 11 (S43), and waits until it is received (N in S43).

  When the “step 2 start” command is received from the first SDH transmission apparatus 11 (Y in S43), the CPU system package of the third SDH transmission apparatus 13 switches the line from the 1 system to the 0 system (S44).

  Thereafter, the CPU system package of the third SDH transmission apparatus 13 transmits a “step 2 ok” command to the first SDH transmission apparatus 11 (S45). The accommodation changing operation of the third SDH transmission apparatus 13 is thus completed.

  FIG. 10 is a diagram for explaining the procedure of the accommodation changing work in the SDH transmission system according to the present embodiment. As an initial state, it is assumed that the first SDH transmission device 11 and the second SDH transmission device 12 are redundantly connected by a 0-system optical fiber 14 and a 1-system optical fiber 15, and the 0-system optical fiber 14 is an active system.

  First, as procedure (1), the operator operates the control device 16 to set the first SDH transmission device 11 to the first accommodation change mode, set the second SDH transmission device 12 to the second accommodation change mode, The 3SDH transmission apparatus 13 is set to the third accommodation change mode.

  Next, as a procedure (2), the operator changes the connection of the 1-system optical fiber 15 from the second SDH transmission device 12 to the third SDH transmission device 13. At this time, the 0-system interface card of the first SDH transmission apparatus 11 and the 0-system interface card of the second SDH transmission apparatus 12 are connected by the 0-system optical fiber 14, and the 1-system interface card of the first SDH transmission apparatus 11 and the third SDH transmission apparatus are connected. 13 1-system interface cards are connected by the 1-system optical fiber 15.

  Next, as a procedure (3), the operator operates the control device 16 to send a “start accommodation change step 1” command to the first SDH transmission device 11. The first SDH transmission apparatus 11 that has received the “accommodation change step 1 start” command automatically executes the processes from S21 to S25 in the flowchart shown in FIG. 7 without requiring the operator's operation. That is, first, a command “step 1 start” is sent to the second SDH transmission apparatus 12 and the third SDH transmission apparatus 13. The second SDH transmission apparatus 12 that has received “step 1 start” from the first SDH transmission apparatus 11 controls the 1-system interface card to the Lock Out state as shown in S31 of the flowchart of FIG. In addition, the third SDH transmission apparatus 13 that has received “step 1 start” from the first SDH transmission apparatus 11 switches the line from the 0 system to the 1 system as shown in S41 of the flowchart of FIG. The second SDH transmission apparatus 12 and the third SDH transmission apparatus 13 that have completed the respective operations transmit a “step 1 ok” command to the first SDH transmission apparatus 11. Upon receiving this “step 1 ok” command, the first SDH transmission apparatus 11 switches the line from the 0 system to the 1 system, as shown in S25 of the flowchart of FIG.

  Next, as a procedure (4), the operator changes the connection of the 0-system optical fiber 14 from the second SDH transmission device 12 to the third SDH transmission device 13. At this time, the 0-system interface card of the first SDH transmission apparatus 11 and the 0-system interface card of the third SDH transmission apparatus 13 are connected by the 0-system optical fiber 14, and the 1-system interface card of the first SDH transmission apparatus 11 and the third SDH transmission apparatus are connected. 13 1-system interface cards are connected by the 1-system optical fiber 15.

  Next, as a procedure (5), the operator operates the control device 16 and sends a command “start accommodation change step 2” to the first SDH transmission device 11. The first SDH transmission apparatus 11 that has received the “accommodation change step 2 start” command automatically executes the processes from S27 to S28 in the flowchart shown in FIG. 7 without requiring the operator's operation. That is, first, a “step 2 start” command is sent to the third SDH transmission apparatus 13. The third SDH transmission apparatus 13 that has received “step 2 start” from the first SDH transmission apparatus 11 switches the line from the 1-system to the 0-system as shown in S44 of the flowchart of FIG. The third SDH transmission apparatus 13 that has completed the switching from the 1-system to the 0-system transmits a “step 2 ok” command to the first SDH transmission apparatus 11. Upon receiving this “step 2 ok” command, the first SDH transmission apparatus 11 switches the line from the 1st system to the 0th system as shown in S29 of the flowchart of FIG. 7, and the accommodation changing operation is completed.

  As in the procedures (3) and (5) described above, in the accommodation change operation using the accommodation change mode according to the present embodiment, the “accommodation change step 1 start” and “accommodation change step 2 start” are performed from the control device 16. A plurality of processes are automatically performed in the first SDH transmission apparatus 11, the second SDH transmission apparatus 12, and the third SDH transmission apparatus 13 only by sending a command to the first SDH transmission apparatus 11. Thereby, the procedure of accommodation change work is simplified and work time and work cost can be reduced. Moreover, the occurrence of work mistakes can be suppressed by simplifying the procedure of the accommodation changing work.

  The present invention has been described based on the embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications are possible depending on the combination of each component and each processing process, and such modifications are within the scope of the present invention. is there.

  DESCRIPTION OF SYMBOLS 10 SDH transmission system, 11 1st SDH transmission apparatus, 12 2nd SDH transmission apparatus, 13 3rd SDH transmission apparatus, 140 system optical fiber, 15 system 1 optical fiber, 16 control apparatus, 18 SDH transmission apparatus, 20 CPU system package, 21 0 system interface card, 22 1 system interface card.

Claims (6)

In an SDH transmission system comprising a first SDH transmission device, a second SDH transmission device, a third SDH transmission device, and a control device that controls the first SDH transmission device, the second SDH transmission device, and the third SDH transmission device,
The first SDH transmission apparatus can be set to a first accommodation change mode for transmitting / receiving a control signal for line switching between the first SDH transmission apparatus, the second SDH transmission apparatus, and the third SDH transmission apparatus. Configured,
The second SDH transmission device is configured to be set to a second accommodation change mode for transmitting and receiving a control signal for line switching between the first SDH transmission device and the second SDH transmission device,
The third SDH transmission device is configured to be set to a third accommodation change mode for transmitting and receiving a control signal for line switching between the first SDH transmission device and the third SDH transmission device,
When changing from the state in which the first SDH transmission device and the second SDH transmission device are connected in a 1 + 1 redundancy configuration to the state in which the first SDH transmission device and the third SDH transmission device are connected in a 1 + 1 redundancy configuration, wherein the control device sets the first 1SDH transmission device to the first receiving change mode, setting the first 2SDH transmission device to the second accommodating change mode, the second 3SDH transmission device to the third accommodation change mode Set,
When the first SDH transmission device receives an accommodation change start instruction from the control device, the first SDH transmission device set in the first accommodation change mode and the second SDH transmission set in the second accommodation change mode A control signal is communicated between the apparatus and the third SDH transmission apparatus set in the third accommodation change mode, and a process for switching a plurality of lines is performed.   2. The SDH transmission system according to claim 1, wherein the processing for line switching includes a line switching process from the 0 system to the 1 system and a line switching process from the 1 system to the 0 system.   The SDH transmission system according to claim 1 or 2, wherein the control signal is transmitted using K1 / K2 bytes of section overhead of an SDH frame. Each of the first SDH transmission device, the second SDH transmission device, and the third SDH transmission device has the SDH transmission device in the first accommodation change mode, the second accommodation change mode, and the third accommodation change mode. The SDH transmission system according to any one of claims 1 to 3, further comprising an SDH switching processing program for setting to any one. The control signal transmitted / received between the first SDH transmission device set in the first accommodation change mode and the second SDH transmission device set in the second accommodation change mode is transmitted from the first SDH transmission device to the second SDH transmission device. A first command transmitted to the second SDH transmission apparatus and used to prevent the second SDH transmission apparatus from switching to the first system, and after the second SDH transmission apparatus prevents the second SDH transmission apparatus from switching to the first system, 5. The SDH transmission system according to claim 1, wherein the SDH transmission system is one of second commands transmitted to the first SDH transmission apparatus. The control signal transmitted and received between the first SDH transmission device set in the first accommodation change mode and the third SDH transmission device set in the third accommodation change mode is transmitted from the first SDH transmission device to the first SDH transmission device. A third command transmitted to the third SDH transmission apparatus to switch the third SDH transmission apparatus from the 0-system to the 1-system; from the third SDH transmission apparatus after the third SDH transmission apparatus is switched from the 0-system to the 1-system; A fourth command for switching the first SDH transmission apparatus transmitted to the first SDH transmission apparatus and receiving the second command from the 0 system to the 1 system, and the first SDH transmission apparatus switched from the 1 system to the 0 system Later, a fifth frame is transmitted from the first SDH transmission apparatus to the third SDH transmission apparatus to switch the third SDH transmission apparatus from the 1-system to the 0-system. SDH transmission system according to claim 5 is either de.

Images