JP2004274241A - Circuit switchover device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent an undesired malfunction even when an interface part or a switchover control part is inserted/removed for maintenance during operation in a circuit switchover device which deals with an SDH (synchronous digital hierarchy) data signal string. <P>SOLUTION: An active/reserve interface part 81 sends first block information containing the alarm information of the SDH signal string, received K1K2 bytes, packaging state information of the present interface part and an interface class to a switchover control part 80 as a receiving side serial control signal stream 100 while multiplexing them on a time-sequential place corresponding to the packaging position on a single serial signal. On the basis of the first block information received from the active/reserve interface part 81, the switchover control part 80 multiplexes second block information containing control object information, control validity information, system selection information and transmitted K1K2 bytes by the respective parts, and sends the resultant information to each part as a transmitting side serial control signal string 110 after a synchronizing pattern. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a line switching device, and more particularly, to a line switching device that handles a SDH (Synchronous Digital Hierarchy) data signal sequence and performs switching using a K1K2 byte in an SOH (Section Overhead).
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in an SDH (Synchronous Digital Hierarchy) system, a redundantly configured device is often used to relieve a transmission line failure or a device failure. As one of the methods, there is a method called MSP (Multiple Section Protection), and its specification is based on ITU-TG. 783 and TELCRODIA GR-253-CORE. In the MSP, switching control is performed based on K1, K2 bytes in SOH (Section Over Head) in the SDH signal, line deterioration information, device failure information, and the like. As a switching method in this case, a Bi-Directional method in which bidirectional communication is performed with an opposing device using the K1 and K2 bytes, and control is performed such that both the own station and the opposing station select the same system. In addition, there is a Uni-Directional system in which switching is performed based on the failure detection result of the own station regardless of the K1K2 byte information from the opposing device, and further, localization for switching back to the active system with a higher priority when the failure is recovered. There is a non-local switching method in which no priority is set for the switching method and the active / standby mode, and no failback is performed even if a failure is recovered. The switching configuration for realizing the MSP is classified into a line protection system in which both the interface unit and the transmission line are duplicated, and a unit protection system in which only the devices are duplicated and the transmission line with the opposing device is one. Line protection is mainly used for optical signal transmission lines, and unit protection is used for electric signal transmission lines.
[0003]
A conventional line switching apparatus that handles a SDH data signal sequence and performs switching using K1K2 bytes in an SOH is disclosed in, for example, JP-A-2002-164863. The operation of the conventional line switching device will be described with reference to the drawings with reference to JP-A-2002-164863.
[0004]
Referring to FIG. 7, an SDH interface unit 810 and a system selection unit 811 exist for each line, and a switching control unit 800 controls switching of all lines. The SDH interface unit 810 includes an optical signal transmission / reception unit for an optical transmission line or an electric signal transmission / reception unit for an electric transmission line, and generates identification signals 910w and 910p in accordance with the types of these interface units. . Also, the SDH signal monitoring section 901 monitors the SDH signals received from the transmission paths 901w and 901p corresponding to the working system and the protection system, and when an error is detected, generates line failure alarms 912w and 912p according to the content of the error. The received APS bytes 914w and 914p, which are obtained by extracting K1 and K2 bytes from the MSOH (Multiplex Section Overhead) byte of the received SDH signal, are output. It is inserted into the K1 and K2 bytes in the received SDH signal. On the other hand, the switching control unit 800 multiplexes a switching control signal in which the identification code of each line is inserted based on the line failure alarms 912w and 912p, the received APS bytes 914w and 914p, and the identification signals 910w and 910p for each line and performs switching. A signal 922 is generated and output to the online bus 809. The system selection unit 811 compares the identification code included in the multiplexed switching signal 922 with a preset identification code unique to each line, extracts a matching switching signal from the switching signal 922, and extracts the extracted switching signal. Thus, one of the SDH signals multiplexed on the signal paths 902w and 902p is selected, and the transmission signal 904 is output, thereby switching between the working and protection lines.
[0005]
[Patent Document 1]
JP-A-2002-148663
[0006]
[Problems to be solved by the invention]
However, the conventional line switching device described in JP-A-2002-148663 has the following problem.
[0007]
The first problem is that erroneous switching may occur during maintenance or the like.
[0008]
In the conventional line switching apparatus of FIG. 7, a case is considered in which the switching control unit 800 is inserted and removed for maintenance. First, when the switching control unit 800 is removed from the device and the operation is stopped, either the working system or the standby system is selected based on the signal multiplexed with the switching signal 922 indicating the working system or the standby system. In addition, since the connection between the switching control unit 800 and the system selection unit 811 is disconnected, a system to be selected by the selection circuit in the system selection unit 811 cannot be determined, and erroneous switching may occur. There is a problem.
[0009]
Also, when the switching control unit 800 is inserted, the fault detection circuit in the switching control unit 800 detects an erroneous line fault alarm due to noise or the like (due to chattering) on the line fault alarms 912w and 912p, and performs switching control. There is a problem that unnecessary switching may occur when the unit 800 generates the switching signal 922 based on an erroneous line failure alarm.
[0010]
When the SDH interface unit 810 is inserted and removed, unnecessary line failure alarms may be repeated until the operation becomes stable due to the noise generation phenomenon due to chattering. There is a problem that unnecessary switching may occur by generating the switching signal 922 based on the
[0011]
The second problem is that as the number of lines (systems) increases, the device configuration becomes complicated.
[0012]
The reason is that, in the conventional line switching device, each physical signal of the identification signal, the K1K2 byte, and the circuit failure alarm is independently communicated with the switching control unit 800 for each interface unit. As the number increases, the number of signal lines increases and the configuration of the device becomes complicated.
[0013]
A third problem is that unnecessary switching may occur depending on the configuration of MSP switching.
[0014]
The reason is that in the MSP switching, the switching is controlled based on the line degradation information calculated from the parity bit in the SOH and the state of the K1K2 byte, but one SDH signal is transmitted to the two working / standby interface units 810 by the SDH signal 901w. , 901p, and in the case of the unit protection method in which transmission is performed on one transmission line, when a failure occurs in the transmission line, both the working interface unit and the SOH termination circuit of the backup interface unit are connected to the line. May detect fault alerts. At this time, when one of the line fault alarms is generated, the switching control unit 800 may detect the line switch alarm and cause the switching due to the error of each line fault alarm detection time. However, when a failure occurs on one transmission line, unnecessary switching occurs because the line cannot be rescued even if the selected interface unit is switched. In order to prevent this unnecessary switching, it is necessary to change the switching conditions such as the line failure detection time depending on the switching configuration. Therefore, it is not possible to realize a device configuration having a plurality of systems and a mixture of line protection and unit protection. In addition, there is a problem that the setting is troublesome even when the setting is feasible, and there is a possibility that an operator may make a setting error.
[0015]
SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to prevent an unnecessary malfunction from occurring even when an interface unit or a switching control unit is inserted or removed during maintenance during operation.
[0016]
Further, another object of the present invention is to simplify the above-described problems without increasing the number of physical interfaces between the interface unit and the switching control unit even when the number of lines (systems) increases.
[0017]
[Means for Solving the Problems]
In order to achieve the above object, a line switching device according to the present invention is a line switching device which handles an SDH data signal sequence and performs switching using a K1K2 byte in an SOH. A signal processing unit that selects one of the SDH data signal sequences output from the working or protection interface unit by the switching control unit and outputs the selected SDH data signal sequence to a downstream device. Provided as one system, the working and protection interface unit receives the received K1K2 bytes extracted from the SOH, alarm information indicating an error caused by monitoring the SDH data signal sequence, and mounting state information indicating a mounting position of the own interface unit. Time series corresponding to the mounting position on one serial signal including the first block information A first transmitting means for multiplexing the first serial control signal sequence and transmitting the first serial control signal sequence to the switching control unit as a first serial control signal sequence, wherein the switching control unit receives the first serial control signal from the working and standby interface units Switching control means for performing line switching control based on the first block information from a column.
[0018]
Further, in the above-described line switching apparatus, a plurality of the one system are provided in the own apparatus.
[0019]
Further, in the above line switching device, the SDH data signal sequence received from the upstream device is transmitted to each of the working and protection interface units, and one of the SDH data signal sequences output from the working or protection interface unit is selected. The one system is characterized in that a common unit for transmitting the selected SDH data signal sequence to an upstream device is provided in the one system.
[0020]
Further, in the above line switching apparatus, the first block information includes an interface type supported by the working or protection interface unit, and the switching control unit performs switching of the switching extracted from the first serial control signal sequence. Even when the alarm information serving as a condition is detected within a predetermined period of time, the alarm information is used to determine switching according to the interface type.
[0021]
Further, in the above line switching device, the first serial control signal sequence is obtained by multiplexing the first block information for each interface unit.
[0022]
Further, in the above-described line switching device, the switching control unit includes, after a frame synchronization pattern indicating a head of a frame, control target information indicating a system identification, and control validity information indicating whether switching control is valid or not. The second block information including the system selection information for identifying the selection of the working system or the protection system and the transmission K1K2 byte information to be multiplexed on the SOH is controlled by the working interface unit, the protection interface unit, And a signal processing unit for multiplexing the signals, multiplexing the signals into one serial signal, and transmitting the multiplexed signals as a second serial control signal sequence.
[0023]
Further, in the above line switching device, the second transmitting means allocates the second block information of the signal processing unit multiplexed to the second serial control signal sequence to the common unit, and the allocated second block information is assigned to the common unit. The second serial control signal sequence is transmitted to the common unit.
[0024]
Further, in the above line switching device, the working and protection interface unit establishes control frame synchronization from the second serial control signal sequence received from the switching control unit, and based on the mounting position information, Multiplexing means for extracting only information corresponding to the own interface unit of the own system to be controlled in the serial control signal sequence and performing switching SOH multiplexing processing based on the extracted information. .
[0025]
Further, in the above line switching apparatus, the multiplex processing means performs the switching only when detecting that the content of the control validity information is valid in the information extracted from the received second serial control signal sequence. The transmission K1K2 bytes are updated by SOH multiplex processing.
[0026]
Further, in the above line switching apparatus, the signal processing unit extracts the control validity information in the block information of the signal processing unit corresponding to the own system from the received second serial control signal sequence, and extracts the extracted control validity. A first switching unit that performs a switching process based on the system selection information in the second block information of the signal processing unit corresponding to the own system only when detecting that the content of the information is valid; I have.
[0027]
Further, in the above line switching device, the common unit extracts the control effective information in the second block information of the common unit corresponding to the own system from the received second serial control signal sequence, and extracts the extracted control information. A first switching unit that performs a switching process based on the system selection information in the second block information of the common unit corresponding to the own system only when detecting that the content of the valid information is valid. I have.
[0028]
Further, in the above-described line switching device, the first transmitting means may determine from the mounting position information of the own interface unit in advance when synchronization of the control frame of the second serial control signal sequence received from the switching control unit is established. The method is characterized in that the first block information is inserted at a predetermined time-series location and the first serial control information is transmitted to the switching control unit.
[0029]
Further, in the above-mentioned line switching device, the first block information of each interface unit multiplexed on the first serial control signal includes detection valid information, and the first transmitting unit receives a signal from the switching control unit. The validity of the detection in the first block information corresponding to the own interface unit is determined only when the control frame synchronization is established when the control frame synchronization of the second serial control signal sequence is established. Is enabled and multiplexed with the first serial control signal sequence to notify the switching control unit at the receiving end that synchronization has been established.
[0030]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, a first embodiment of the present invention will be described in detail with reference to the drawings.
[0031]
FIG. 1 is a block diagram showing an example of a configuration inside a line switching device according to an embodiment of the present invention. In FIG. 1, the first system (system number 1 and abbreviation: SYS1) includes a working interface unit 81-1a (abbreviation: SYS1-A), a standby interface unit 81-1b (abbreviation: SYS1-B), The entire system (system numbers 1 and 2) that includes a signal processing unit 83-1d (abbreviation: SYS1-D) and a common unit 83-1c (abbreviation: SYS1-C) and extracts and generates control signals related to switching ,...) Are constituted by a common switching control unit 80. The second and subsequent systems (system numbers 2 and later) are omitted because they have the same configuration as system number 1. The SYS1-A working interface unit 81-1a and the SYS1-B spare interface unit 81-1b have the same configuration. In the following description, for convenience of explanation of the blocks in the working interface unit 81-1a, the backup interface unit 81-1b, the common unit 82-1c, and the signal processing unit 80-1c, the system number 1 is assigned to each unit. By adding -1a (1: system number, a: A under the block abbreviation), -1b, -1c, -1d after the given code, the identification of the system number and the block is clarified. Also, for the sake of explanation, -1a, -1b, -1c, and -1d may be added in the system number 1 for clarifying which part of the signal is for convenience of description.
[0032]
The opposing device (upstream device) in FIG. 1 is a device having an APS (Automatic Protection Switching) function, and is, for example, a line switching device or a wired terminal (MUX) of the present invention. Further, the next stage (downstream device) in FIG. 1 is a device having an APS (Automatic Protection Switching) function, and is, for example, a line switching device, a wired terminal (MUX), or the like of the present invention. Note that the line switching device of the present invention also has a function as a normal transmission device (relay), but the description is omitted in the present invention.
[0033]
First, on the receiving side of the SYS1-A in FIG. 1, a receiving SDH data signal sequence 10-1a obtained by branching and outputting a received SDH data signal sequence 101 from an opposite device (not shown) by a branch circuit 40-1c of a SYS1-C common unit. , Frame synchronization is established by the SOH termination circuit 1-1a, and line alarm information obtained by calculating parity bits in the SOH and extracted alarm information 12-1a representing alarms such as frame synchronization loss, and K1 and K2 in the SOH. The extracted K1K2 byte 13-1a from which the byte has been extracted is sent to the K1K2 transmitting / receiving unit 50-1a, and the termination working SDH data signal sequence 11-1a is sent to the selection circuit 31-1d.
[0034]
In the K1K2 transmitting / receiving section 50-1a of FIG. 1, referring to FIG. 2, the alarm generating circuit 2-1a converts the extracted alarm information 12-1a into a plurality of bits of information and outputs alarm information 15-1a. The K1K2 extraction circuit 3-1a outputs the received K1K2 byte 14-1a protected by the extracted K1K2 byte 13-1a. The mounting state determination circuit 4-1a is a circuit for detecting information for specifying a position such as a system number or a working / standby where the interface unit 81 is mounted, and mounting position information 19 input from outside (for example, a clamp value). -1a to determine the mounting position of the interface unit 81, and generate and output mounting information 16-1a. The interface type generation circuit 5-1a outputs information for specifying the type of the interface unit 81 such as an optical interface or an electrical interface as an interface type 17-1a. The serial information transmitting / receiving unit 6-1a receives the received K1K2 byte 14-1a, the alarm information 15-1a, the mounting information 16-1a, and the interface type 17-1a, and receives the input from the serial control information generating circuit 22 described later. The serial data is converted into serial information in accordance with the timing of the output serial control signal sequence 110 and the reception serial control signal sequence 100 is output.
[0035]
Also, on the transmitting side of SYS1-A in FIG. 1, control frame synchronization is established from a control frame synchronization pattern multiplexed on a transmitting side serial control signal sequence 110 of the serial control information generating circuit 22, which will be described later. Using the timing signal generated on the basis of 1a, only the information for the own interface unit 81 is extracted from the transmission side serial control data signal sequence 110, and the transmission K1K2 byte 18-1a to be multiplexed in the SDH data signal sequence to be transmitted is obtained. Output to the SOH multiplexing circuit 7-1a. The SOH multiplexing circuit 7-1a converts the transmission K1K2 byte 18-1a and a predetermined SOH signal into a reception data signal sequence 431 input from a preceding stage (not shown) via the SYS-1D signal processing unit 83-1d. It is multiplexed and output as a transmission working SDH data signal sequence 20-1a.
[0036]
Next, the configuration of the SYS1-B side spare interface unit 81-1b of FIG. 1 is the same as that of the SYS1-A side working interface unit, and therefore the description is omitted.
[0037]
Next, the SYS1-D signal processing unit 83 shown in FIG. 1 converts the terminal working SDH data signal sequence 11-1a from the working interface unit 81-1a and the terminal protection SDH data signal sequence 11-1b from the protection interface unit 81-1b. According to the system selection information 46-1d input to the selection circuit 31-1d and output from the selection information extraction circuit 32-1d in the switching information extraction unit 70-1d to be described later, either the working / standby interface unit 81 is selected. Then, it transmits the transmission data signal sequence 401 to a downstream device (not shown) (the next stage in FIG. 1).
[0038]
The switching information extraction unit 70-1d in FIG. 1 includes a control frame synchronization circuit 34-1d, a timing generation circuit 33-1d, and a selection information extraction circuit 32-1d. Control frame synchronization is established from the control signal sequence 110, and only information for the own system is extracted from the output side serial control signal sequence 110 according to the system number 47-1d input from the outside, and the information is multiplexed in the serial control signal sequence. Only when the control validity information is valid, the system selection information 46-1d is updated and output to the selection circuit 31-1d.
[0039]
Next, the common unit SYS1-c is a circuit provided in accordance with the device configuration. On the receiving side, the received SDH data signal sequence 101 transmitted through one transmission line is transmitted to the working interface unit 81-1a and the standby interface unit 81-1. -1b, and on the transmitting side, after selecting one of the transmission working SDH data signal sequence 20-1a of the working interface unit 81-1a and the transmission protection SDH data signal sequence 20-1b of the protection interface unit 81-1b, The transmission SDH data signal sequence 201 is output to an upstream device (not shown in FIG. 1).
[0040]
The selection circuit 31-1c and the switching information extraction unit 70-1c of FIG. 1 have the same configuration as the selection circuit 31-1d and the switching information extraction unit 70-1d, and are extracted and generated from the output side serial control signal sequence 110. According to the system selection information 46-1c, one of the transmission current SDH data signal sequence 20-1a and the transmission standby SDH data signal sequence 20-1b of the standby interface unit is selected, and the transmission SDH data signal sequence 201 is output.
[0041]
Next, the switching control unit 80 in FIG. 1 includes a reception information extraction circuit 21, a serial control information generation circuit 22, and a time division switching control circuit 23. First, the reception information extraction circuit 21 converts the reception serial control signal sequence 100 transmitted from the interface unit 81 of each system according to the output timing of the transmission serial control signal sequence 110 output from the serial control information generation circuit 22 described later. The interface type 120, the mounting information 130, the detection validity information 140, the alarm information 150, the reception K1K2 bytes are obtained from the information received and multiplexed by the interface unit 81 of each system based on the extraction timing 221 generated by the serial control information generation circuit 22. 160 is output to the time division switching control circuit 23.
[0042]
The time division switching control circuit 23 of FIG. 1 determines a system to be selected for each system according to the information extracted by the reception information extraction circuit 21 and generates K1 and K2 bytes to be multiplexed on the SOH of the output SDH signal sequence. The control frame synchronization pattern 170 representing the head of the transmission side serial control signal sequence, the control target 180, the control validity information 190 indicating that the control is valid, the system selection information 200, and the transmission K1K2 byte 210 are transmitted to the serial control information generation circuit 22. Output. In this case, when a failure report (alarm information 150) is received from the active interface unit 81-1a, the time division switching control circuit 23 sets the system selection information to "standby system" in order to instruct system switching. Set. In accordance with the output of the time division switching control circuit 23, the serial control information generation circuit 22 converts the control frame synchronization pattern, the system selection information for all systems, and the K1K2 bytes multiplexed to the SOH in the SDH signal string into one serial data. , As the transmission side serial control signal 110.
[0043]
Referring to FIG. 5, signals on reception-side serial control signal sequence 100 and transmission-side serial control signal sequence 110 of switching control unit 80 in the line switching apparatus in FIG. 1 are shown in time series, and the configuration in each signal sequence is shown. FIG. FIG. 5 will be described below.
[0044]
In the time-division switching control circuit 22 in the switching control unit 80 of FIG. 1, following the control frame synchronization pattern indicating the head of the transmission side serial control signal sequence 110, the working interface unit 81, the backup interface unit 81, and the signal processing unit 83 Then, the serial control signal 110 is generated in time series with the system number 1 to the system number n (n is a positive integer of 1, 2,...) As one control frame in the order of the common unit 82, and this is repeated. The information (referred to as block information in the present invention) for each system in the transmission-side serial control signal sequence 110 in FIG. 5 includes a control target indicating a system number, control validity information indicating that control is valid, and an interface unit to be selected. 81, and transmission K1K2 bytes multiplexed on the SOH of the SDH signal to be transmitted. (FIG. 5- (2)).
[0045]
The interface unit 81, the signal processing unit 83, and the common unit 82 of each system establish control frame synchronization from the received transmission-side serial control signal sequence, and externally input mounting information 19 (for the interface unit 81) or the system. According to the number 47 (in the case of the signal processing unit 83 and the common unit 82), only the control information for the control target of the own system is extracted, and in the interface unit 81, the receiving side serial number is The timing (time sequence location) for outputting the control signal sequence 100 is determined, and the interface type, mounting information, detection valid information indicating that synchronization is established in the control frame synchronization circuit, alarm information, and reception K1K2 bytes are obtained. The block information is converted into a serial signal by the serial information transmitting / receiving unit 6 and output. Things, the information from all the system interface unit 81 to the reception information extracting circuit 21 of the switching control unit 80 without receiving side serial control signal string 100 outputted from the interface unit 81 collides is delivered. (FIG. 5- (1)).
[0046]
As shown in FIG. 5, the lengths of the reception serial control signal sequence 100 and the transmission serial control signal sequence 110 for each control target are the same, and one control frame length of the reception serial control signal sequence 100 and the transmission serial control signal sequence 110 1 control frame lengths are matched, so that the receiving side serial control signal sequence 100 output from each interface unit 81 does not collide, and the information from the interface units 81 of all the systems is received. 21.
[0047]
Next, the operation of the embodiment of the present invention will be described in detail with reference to FIGS.
[0048]
Referring to FIG. 1, a unit protection configuration is provided in which a common unit is provided in addition to the working interface unit, the backup interface unit, and the signal processing unit to remedy a failure of a device. FIG. 3 is a diagram showing an embodiment of the serial information transmitting / receiving section 6 in the embodiment of FIG. 1. In FIGS. 1 and 3, the serial information transmitting / receiving section 6 of the SYS1-A working interface section is shown. -1a, the received K1K2 byte 14-1a extracted from the SOH signal of the received working SDH data signal sequence 10-1a input to the SOH termination circuit 1-1a via the branch circuit 40-1 and protected, and the SOH The mounting position is specified based on the alarm information 15-1a obtained by converting the extracted alarm information 12-1a detected by the terminating circuit 1-1a into a plurality of bits by the alarm generation circuit 2-1a and mounting position information 19-1a provided from outside. The mounting information 16-1a, an interface type 17-1a for specifying a difference between an electrical interface and an optical interface, and a serial Output serial control signal sequence 110 of the control information generating circuit 22 is input. In the serial information transmitting / receiving unit 6-1a, the control frame synchronization circuit 65-1a establishes control frame synchronization of the output side serial control signal sequence 110, and the timing generation circuit 66-1a outputs the output side serial control signal in accordance with the mounting information 16-1a. A timing signal 661-1a for extracting only information for the interface unit 81 from information multiplexed on the control signal sequence 110, and detection validity information indicating that synchronization is established in the control frame synchronization circuit 65-1a. 662-1a, and generates and outputs reception-side timing 663-1a for determining the output timing of the reception-side serial control signal sequence 100 to be output to the switching control unit 80. When the control frame synchronization is established by the control frame synchronization circuit 65-1a, the serial information multiplexing circuit 64-1a receives the reception K1K2 byte 14-1a and the alarm information 15-1a according to the reception timing 663-1a. , The mounting information 16-1a, the interface type 17-1a, and the detection validity information 662-1a are multiplexed into one serial signal and output as a receiving-side serial control signal sequence 100. The receiving-side serial control signal sequence 100 has a bus structure, and outputs the reception-side serial control signal sequence 100 according to the mounting position information 19 input to the serial information transmitting / receiving unit 6 of the interface unit 81 of each system (time series). By determining the (upper place), the information is sent to the reception information extraction circuit 21 of the switching control unit 80 without collision of the receiving side serial control signal sequence 100 output from each interface unit 81.
[0049]
The reception information extraction circuit 21 of the switching control unit 80 extracts information in the reception-side serial control signal sequence 100 in accordance with an extraction timing signal 221 of the serial control information generation circuit 22, which will be described later, and performs interface type, mounting information, alarm information, reception The K1K2 bytes and the detection valid information are detected in a time division manner for all the systems and output to the time division switching control circuit 23. In accordance with the information from the interface unit 81 of each system, the time-division switching control circuit 23 determines that the system number, the selected system, the K1 and K2 bytes to be multiplexed on the output SDH data signal sequence, and that the control information to be output are valid. A control frame synchronization pattern representing the control valid information shown and the head of the output side serial control signal sequence is generated and output to the serial control information generation circuit 22. In the serial control information generation circuit 22, the control target information for all systems output in a time division manner from the time division switching control circuit 23, control validity information indicating that the control is valid, system selection information, transmission K1K2 bytes and output The frame synchronization pattern indicating the head of the side serial control signal sequence is multiplexed and output as the transmission side serial control signal sequence 110. In the serial information transmitting / receiving section 6-1a of the working interface section 81-1a, control frame synchronization is established by the control frame synchronization circuit 65-1a, and the timing signal 661-generated by the timing generation circuit 66-1a based on the mounting information 16-1a. 1a, only information for the interface unit 81 is extracted, and the transmission K1K2 byte 18-1a to be multiplexed with the SDH signal sequence output only when the control valid information in the transmission side serial control signal sequence 110 is valid is updated and output. . The SOH multiplexing circuit 7-1a multiplexes the one transmission K1K2 byte 18-1a and a predetermined SOH signal on the reception data signal sequence 431 input via the signal processing unit 83-1d, and transmits the current SDH data signal sequence 10- Output as 1a. Since the operation of the SYS1-B spare interface unit is the same as that of the SYS1-A working interface unit, the description is omitted.
[0050]
In the switching information extraction unit 70-1d of the signal processing unit SYS1-d, the control frame synchronization circuit 34-1d receives the control frame synchronization signal 44-1d from the transmission side serial control signal sequence 110 and the outside (for example, a clamp value). The timing generation circuit 33 generates the timing signal 45 for the own signal processing unit 83 according to the system number 47-1d to be executed. Further, in accordance with the generated timing signal 45, the selection information extracting circuit 32 extracts control valid information and system selection information for the own signal processing unit 83, and updates the system selection information 46-1d when the control valid information is valid. , The interface unit 81 to be selected by the selection circuit 31-1d is determined.
[0051]
The switching information extraction unit 70-1c of the common unit SYS1-C is the same circuit as the switching information extraction unit 70-1d of the signal processing unit 83-1d, and is input from the transmission side serial control signal sequence 110 and the outside. In accordance with the system number 47-1c (the same value as the system number 47-1c), the control valid information and the system selection information for the own common unit 82 are extracted, and when the control valid information is valid, the system selection information 46-1c is updated. Then, the interface unit 81 to be selected by the selection circuit 31-1c is determined.
[0052]
Next, in the line switching device of FIG. 1, when the switching control unit 80 is pulled out of the line switching device and the operation is stopped, the control frame synchronization pattern is not multiplexed on the transmission side control signal sequence 110. In the signal processing unit 83, the synchronization in the control frame synchronization circuit is not established, and the system selection state before the operation stop is maintained. After that, when the switching control unit 80 is mounted, the transmission-side serial control is performed by multiplexing the control frame synchronization pattern with the control valid information multiplexed on the transmission-side serial control signal sequence 110 output from the switching control unit 80 being invalidated. The signal sequence 110 is output. During this time, in the common unit 82 and the signal processing unit 83 of each system, the control valid information is invalid even if the control frame synchronization is established, so that the state before the switching control unit 80 is mounted is maintained. ing. On the other hand, in the working and backup interface unit 81 of each system, control frame synchronization is established from the time when the control frame synchronization pattern is multiplexed on the transmission side serial control signal sequence 110, and the reception serial control signal sequence 100 is valid. The receiving side serial control signal sequence 100 is output to the switching control unit 80 together with the detection validity information indicating that there is. The switching control unit 80 determines the current state from the received receiving side serial control signal sequence 100, determines an interface unit 81 (selection of working or standby) to be selected in each system, and then determines the transmitting side serial control signal sequence 110 The control valid information to be multiplexed is output in a valid state. The working and backup interface unit 81 of each system determines K1K2 bytes to be multiplexed on the SOH of the transmission SDH signal according to the control information of the transmission side serial control signal sequence 110, and the signal processing unit 83 and the common unit 82 of each system The system to be selected is determined according to the control information of the transmission-side serial control signal sequence 110, and each system returns to the normal operation state. Further, when the interface unit 81 is mounted from a state where it is removed, the operation of the interface unit is not stable for a while after the interface unit is mounted, so that an erroneous K1K2 byte is detected or alarm information is transiently displayed. Although the occurrence and release may be repeated, control frame synchronization cannot be established from the transmission-side serial control signal sequence 110 until the operation of the interface unit 81 is stabilized. Since the information is not valid and the switching control unit 80 does not detect erroneous information, unnecessary switching does not occur.
[0053]
Next, an operation when the switching control unit 80 and the interface unit 81 are maintained will be described with reference to a block diagram of a line switching device having a plurality of systems having different configurations. FIG. 6 is a block diagram showing the configuration of the line switching apparatus of the present invention. SYS-1 provides a common unit 82-1c in addition to the working interface unit 81-1a and the standby interface unit 81-1b to prevent equipment failure. SYS2 represents a unit protection configuration to be relieved, and a line protection configuration in which SYS2 communicates with the opposing device using the working line and the protection line for the working interface unit 81-2a and the protection interface 81-2b. Also, in FIG. 6, the inside of the working interface units 81-1a and 81-2a, the inside of the spare interface units 82-1b and 82-2b, the inside of the common unit 82-1c, the inside of the signal processing units 83-1d and 83-2d, and the switching Each configuration in the control unit 80 is assumed to be the same as the configuration in each block illustrated in FIG.
[0054]
Consider a case where the switching control unit 80 is inserted and removed for maintenance in the line switching device of FIG. First, when the switching control unit 80 is removed from the device and the operation is stopped, the SYS1-C common unit 82-1c, the SYS1-D signal processing unit 83-1d, and the SYS2-D signal processing unit 83-2d transmit the transmission-side serial control signal. Since the control frame synchronization cannot be established from the column 110, the system selection retains the state before the operation was stopped. Next, when the switching control unit 80 is mounted, first, the control valid state to be multiplexed on the transmission side serial control signal sequence 110 output from the switching control unit 80 is transmitted as invalid, and the state before the switching control unit 80 is mounted. Is output, the transmission-side serial control signal sequence 110 is output. In the interface unit 81 of each system, when the control frame synchronization is established from the transmission-side serial control signal sequence 110, the reception-side serial control signal sequence 100 together with detection validity information indicating that the reception serial control signal sequence 100 is valid. Is output to the switching control unit 80. The switching control unit 80 determines the current state from the received serial control signal sequence 100 on the reception side, determines the interface unit 81 to be selected in each system, and validates the control validity information multiplexed on the serial control signal sequence 110 on the transmission side. Output the status. The interface unit 81, the signal processing unit 83, and the common unit 82 of each system determine the system to be selected and the K1K2 byte to be multiplexed on the SOH of the transmission SDH signal according to the control information of the transmission side serial control signal sequence, and return to the normal operation state. To return.
[0055]
Next, consider a case where the SYS2-A working interface unit 81 is removed and the SYS2-A working interface unit 81 is removed when the SYS2 switching system in FIG. Since the operation of the working interface unit 81-2a is not stable immediately after the mounting of the working interface unit 81-2a, there is a possibility that an erroneous K1K2 byte may be detected or alarm information may transiently repeat generation and release. is there. However, since the control frame synchronization of the transmission-side serial control signal sequence 110 is not established until the operation of the interface unit 81-2a is stabilized, the detection validity information in the reception-side serial control signal sequence 110 becomes invalid, and the switching control unit Since no erroneous information is detected at 80, unnecessary switching does not occur.
[0056]
Further, a system switching operation according to the switching configuration will be described. FIG. 6 shows a unit protection configuration in which SYS1 provides a common unit 81-1c in addition to the active interface unit 81-1a and the standby interface unit 81-1b to rescue equipment failures, and SYS2 is an active interface unit 81-2a and a standby interface. 81-2b has a line protection configuration in which communication with the opposing device is performed using the working line and the protection line. The interface unit 81-1 of the SYS1 has an electric signal interface, and the interface unit 81-2 of the SYS2 has a line protection structure. It is assumed that an optical signal interface is used. In this case, the interface type information generated by the interface unit 81 differs between SYS1 and SYS2. In FIG. 6, assuming that a failure has occurred in the received SDH data signal sequence 101 input from the opposite device to SYS1, the SYS1-A working interface unit 81-1a and the SYS1-B spare interface 81-1b detect alarms respectively. Then, the signal is multiplexed with the receiving side serial control signal and transmitted to the switching control unit 80. The switching control unit 80 controls the switching based on the alarm information from each of the interface units 81-1a and 81-1b. However, based on the interface type multiplexed in the received serial control signal sequence 100, the SYS1 interface unit 81 It detects that it is configured with an interface, and determines that the switching configuration is unit protection. When the alarm information of the SYS1-A working interface section is extracted from the receiving-side serial control signal sequence, the SYS1-A working interface section 81-1a is not immediately judged to be a failure, but the SYS1-B spare interface section 81-a. If the same alarm is detected within a predetermined period of time by extracting and comparing the alarm information of 1b, it is determined that the common unit 82-1c has failed and the switching condition is changed so that the switching is not performed. Further, since the interface type indicating the optical interface is multiplexed in the information from the SYS2, it is determined that the switching configuration is the line protection configuration, and the detection of the alarm information from the working / standby interface as in the SYS1 is performed. By judging switching when an alarm is detected without performing protection, even if the switching configuration differs for each system, it is possible to perform control according to the switching configuration with one switching control unit 80. ing.
[0057]
In the example described with reference to FIGS. 1 and 6, a unit protection configuration is provided in which a common unit 82-1c is provided in addition to the working interface unit 81-1a and the backup interface unit 81-1b to rescue a device failure. In the serial information transmission / reception unit 50 of the interface unit 81, the same circuit as the selection information extraction circuit 32 of the switching information extraction unit 70 is provided together with the transmission K1K2 extraction circuit 67, and system selection information is extracted from the transmission side serial control signal sequence 110. Then, the output of the transmission active SDH data signal sequence 20-1a and the transmission standby SDH data signal sequence 20-1b is directly and exclusively controlled to be output as a transmission SDH data signal sequence 201 to one transmission path, thereby achieving commonality. Transmitting the transmission SDH data signal sequence 201 in the unit protection configuration without providing the unit 1-1c It can become.
[0058]
【The invention's effect】
As described above, the first effect of the present invention is that erroneous switching that occurs at the time of maintenance can be prevented.
[0059]
The reason is that when the switching control unit 80 is inserted and removed for maintenance, first, the switching control unit is removed and the operation stops, and the control frame synchronization cannot be established in the interface unit, the signal processing unit, and the common unit. In the case where the previous control state is held and the operation is restarted by inserting the switching control unit, the previous control state is continued by invalidating the valid information multiplexed on the transmission side serial control signal sequence, and each system By outputting the receiving-side serial control signal sequence to the switching control unit together with detection validity information indicating that the receiving-side serial control signal sequence is valid when the interface unit establishes control frame synchronization from the transmitting-side serial control signal sequence. The switching control unit can determine the interface to be selected in each system by judging the latest state from the serial control signal sequence on the receiving side. This is because can return to normal operation state without causing. Also, when the interface unit is inserted / removed for maintenance, the interface unit is mounted and the operation becomes stable, and the detection valid information in the receiving serial control signal sequence becomes invalid until the control frame synchronization is established from the transmitting serial control signal sequence. This is because erroneous information is not detected by the switching control unit, so that unnecessary switching can be prevented from occurring.
[0060]
A second effect of the present invention is that switching conditions according to the switching configuration can be automatically changed, and unnecessary switching during normal operation can be prevented.
[0061]
The reason is that an interface type indicating a predetermined interface type is multiplexed in the serial control signal sequence on the receiving side, and the switching control unit 80 determines from the interface type that the switching configuration is unit protection, If the same alarm is detected within a predetermined period of time by extracting and comparing alarm information from the interface unit, it is determined that the common unit has failed and control is performed so that switching is not performed. is there.
A third effect is that the apparatus configuration can be prevented from becoming complicated even when the number of systems increases.
[0062]
The reason is that one control frame length of the receiving side serial control signal sequence and the transmitting side serial control signal sequence is the same, and the receiving side serial control signal sequence is transmitted in accordance with the timing of the transmitting side serial control signal sequence, so that each system can be controlled. This is because the number of systems controlled by the switching control unit can be increased without increasing the number of signals transferred between the interface unit, the signal processing unit, the common unit, and the switching control unit.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration example in a line switching device according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration example in a K1K2 transmission / reception unit of FIG. 1;
FIG. 3 is a block diagram showing a configuration example in a serial information transmitting / receiving unit of FIG. 2;
FIG. 4 is a block diagram showing a configuration example in a switching information extraction unit of FIG. 1;
FIG. 5 is a schematic configuration diagram showing a configuration example in a control frame to be superimposed on the reception-side serial control signal 100 or the transmission-side serial control signal 110 of FIG. 1;
FIG. 6 is a block diagram illustrating a configuration example in a line switching device when a plurality of systems are provided.
FIG. 7 is a block diagram showing a configuration inside a conventional line switching device.
[Explanation of symbols]
1 SOH termination circuit
2 Alarm generation circuit
3 K1K2 extraction circuit
4 Mounting state judgment circuit
5 Interface type generation circuit
6 Serial information transmission / reception section
7 SOH multiplexing circuit
21 Reception information extraction circuit
22 Serial control information generation circuit
23 Time-division switching control circuit
31 Selection circuit
32 Selection information extraction circuit
33 Timing Generation Circuit
34 Control frame synchronization circuit
40 branch circuit
70 Switching information extraction unit
80,800 switching control unit
81,810 interface unit
82 common part
83 signal processing unit
811 system selection unit

Claims (13)

In a line switching device that handles an SDH data signal sequence and performs switching using K1K2 bytes in an SOH,
A working interface unit, a protection interface unit, a switching control unit, and the switching control unit selects one of the SDH data signal sequences output from the working or protection interface unit, and transmits the selected SDH data signal sequence to the downstream. And a signal processing unit for outputting to the device as one system,
The working and backup interface unit includes first block information including reception K1K2 bytes extracted from the SOH, alarm information indicating an error caused by monitoring the SDH data signal sequence, and mounting state information indicating a mounting position of the own interface unit. And a first transmitting means for multiplexing the signals in a time-series location corresponding to the mounting position on one serial signal and transmitting the multiplexed signal to a switching control unit as a first serial control signal sequence,
The switching control unit includes: switching control means for performing line switching control based on the first block information from the first serial control signal sequence received from the working and protection interface units. Line switching device. 2. The line switching device according to claim 1, wherein a plurality of said one system are provided in the own device. An SDH data signal sequence received from an upstream device is sent to each of the working and protection interface units, and any one of the SDH data signal sequences output from the working or protection interface unit is selected, and the selected SDH data signal sequence is transmitted. 3. The line switching device according to claim 1, wherein a common unit for transmitting to an upstream device is provided in the one system. The first block information includes an interface type supported by the working or protection interface unit,
The switching control means uses the alarm information, which is a switching condition extracted from the first serial control signal sequence, even if the alarm information is detected within a predetermined period of time, and uses the alarm information to determine the switching according to the interface type. 2. The line switching device according to claim 1, wherein 5. The line switching device according to claim 1, wherein the first serial control signal sequence multiplexes the first block information for each interface unit. The switching control unit, after a frame synchronization pattern indicating the beginning of the frame, control target information indicating the identification of the system, control valid information indicating the validity of the switching control, and selection of the active system or the standby system The second block information including the system selection information to be identified and the transmission K1K2 byte information to be multiplexed on the SOH is divided and multiplexed into the working interface unit to be controlled, the backup interface unit, and the signal processing unit. 2. The line switching device according to claim 1, further comprising a second transmitting unit that multiplexes the signals into one serial signal and transmits the serial signal as a second serial control signal sequence. The second transmitting means allocates the second block information of the signal processing unit multiplexed to the second serial control signal sequence to the common unit, and assigns the allocated second serial control signal sequence to the common unit. 7. The line switching device according to claim 6, wherein the transmission is performed to the common unit. The working and backup interface unit establishes control frame synchronization from the second serial control signal sequence received from the switching control unit, and in the second serial control signal sequence based on the mounting position information. 2. The line switching apparatus according to claim 1, further comprising multiplex processing means for extracting only information corresponding to the own interface unit of the own system to be controlled and performing switching SOH multiplex processing based on the extracted information. The multiplexing means updates the transmission K1K2 bytes by the switching SOH multiplexing process only when detecting that the content of the control validity information is valid in the information extracted from the received second serial control signal sequence. 9. The line switching device according to claim 8, wherein The signal processing unit extracts the control valid information in the block information of the signal processing unit corresponding to the own system from the received second serial control signal sequence, and determines that the content of the extracted control valid information is valid. 9. The line switching device according to claim 8, further comprising a first switching unit that performs a switching process based on the system selection information in the second block information of the signal processing unit corresponding to the own system only when the signal is detected. . The common unit extracts the control valid information in the second block information of the common unit corresponding to the own system from the received second serial control signal sequence, and the content of the extracted control valid information is valid. 10. The line switching device according to claim 9, further comprising: a first switching unit that performs a switching process based on the system selection information in the second block information of the common unit corresponding to the own system only when the line switching is detected. . The first sending unit is configured to set a predetermined time-series location from the mounting position information of the own interface unit when the synchronization of the control frame of the second serial control signal sequence received from the switching control unit is established. The line switching device according to claim 1, wherein the first block information is inserted and the first serial control information is transmitted to the switching control unit. The first block information of each interface unit to be multiplexed on the first serial control signal includes detection valid information,
The first transmitting means determines that the own interface unit is operating normally by establishing control frame synchronization of the second serial control signal string received from the switching control unit, and only when the control frame synchronization is established, That the validity of the detection validity information in the first block information corresponding to the above is made valid and multiplexed with the first serial control signal sequence, thereby notifying the switching control unit of the receiving destination that synchronization has been established. The line switching device according to claim 1, wherein:

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