JP3965626B2 - Redundant configuration communication apparatus and system switching method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a redundant configuration communication apparatus in which a main signal system and a supervisory control system are packaged into a redundant configuration of a 0 system and a 1 system, and the redundant system can be switched at high speed when a switching factor occurs. And a system switching method between the 0 system and the 1 system.
[0002]
[Prior art]
Various devices are known to have a redundant configuration of two systems, 0 system and 1 system, and one of the two systems is a working system and the other is a standby system. During maintenance, etc., the standby system is switched to the active system and the process is continued, and the previous active system is switched to the standby system and maintenance work is performed to improve reliability. Yes. Further, with the spread of the Internet, as a broadband, for example, ADSL (Asymmetric Digital Subscriber Line) has been spread, it is demanded to improve the reliability of the communication system of the subscriber system installed on the station side. .
[0003]
In addition, a 0-system and 1-system subscriber circuit common part is provided for the 0-system and 1-system communication path networks that can operate independently, and the subscriber circuit is connected in accordance with a system switching signal from the communication network. On the other hand, there is known a system switching control circuit for switching and connecting any one of the subscriber circuit common parts of the 0 system and the 1 system and preventing malfunction of the subscriber circuit at the time of the system switching (for example, Patent Document 1). reference).
[0004]
Also, the transmission line in the communication system has a redundant configuration of the 0 system and the 1 system. The transmission line is provided for each predetermined section, and switching means for switching the system when a failure occurs is provided. In order to prevent the switchover to the standby system from causing the system switchover in the subsequent section, alarm information as a pseudo-failure state is sent to the transmission line of the standby system and control of redundant system switchover causes malfunctions. A prevention system is known (see, for example, Patent Document 2).
[0005]
42, for example, a configuration shown in FIG. 42 is generally used, where 100 is a station device, 101 is a user home device, 102 is a modem, 103 is the Internet, 104 is a public network, and 105 is a communication device (subscriber). Line end station apparatus), 106 is a router, 107 is an exchange, and OpS is a higher-level operation system.
[0006]
For example, when the above-described ADSL is applied, the data system communicates on the transmission path from the terminal of the user home device 101 via the modem 102 to the Internet 103 via the communication device 105 of the station device 100 and the router 106. In the voice system, a telephone call is made from the telephone of the user home apparatus 101 through the transmission path to the public network 104 via the communication apparatus 105 of the station apparatus 100 and the exchange 107.
[0007]
Even in such a communication system, a configuration is adopted in which the main part of the station device 100 has a redundant configuration, and even when a failure occurs, the service can be continuously provided by switching to the standby system. For the communication device 105 of the station device 100, for example, the configuration shown in FIG. 43 is common. In the figure, 105 is a communication device, 113-0 to 113-n are subscriber line IF (interface) units each accommodating a single or a plurality of subscriber lines, 114 is a main signal unit, and 115 is supervisory control. , 116-1 and 116-2 are clock units, 117-1 and 117-2 are switch units, and 118-1 and 118-2 are intra-station IFs for connection to the router 106 and the switch 107 in FIG. Interface) sections 119-1 and 119-2 are extended IF (interface) sections.
[0008]
The communication device 105 has a four-block configuration including a main signal unit 114, subscriber line IF units 113-0 to 113-n, a monitoring control unit 115, and clock units 116-1 and 116-2. The other blocks except for 115 blocks have a redundant configuration. In this case, one subscriber line IF unit 113-0 is reserved for n subscriber line IF units 113-1 to 113-n, and this spare subscriber line IF unit 113-0 is set as another unit. The switch unit 117-1 and 117-2 and the in-station IF unit that constitute the main signal unit 114 have an n: 1 redundant configuration that enables switching connection to the subscriber line IF unit by switching means (not shown). The 118-1 and 118-2 and the extended IF units 119-1 and 119-2 have a 1: 1 redundant configuration, and the clock units 116-1 and 116-2 that supply clock signals to the respective units have a 1: 1 configuration. The case where a redundant configuration is adopted is shown.
[0009]
The monitoring control unit 115 performs processing such as setting, control, and failure information collection for the main signal unit 114. The monitoring control unit 115 is configured to be physically independent from the main signal unit 114. The main signal unit 114 is not directly affected. If the monitoring control unit 115 has a redundant configuration, a processor, a backup memory, and the like are mounted on each of the monitoring control units 115 to perform monitoring processing, and to communicate with each other to perform switching control. Due to the complexity, rapid switching is not easy and the cost is increased.
[0010]
[Patent Document 1]
JP-A-6-335036 (5th page, 6th page, FIGS. 1 and 2)
[Patent Document 2]
JP-A-10-117183 (second page, third page, FIGS. 1 and 3)
[0011]
[Problems to be solved by the invention]
In the communication apparatus described above, it is desired to increase the speed of system switching for a redundant configuration, and to reduce the size and cost. Further, in order to increase the number of subscriber lines accommodated, it is desired to have expandability. However, the above-described conventional communication apparatus has a configuration in which at least four types of packages corresponding to blocks are mounted, which requires a lot of space and increases costs due to the production of various types of packages. As for the supervisory control unit 115, when a redundant configuration is applied, as described above, control information between the redundant configurations is transmitted and received to control the system switching. There is a problem that it is difficult to switch the system at the time of occurrence.
[0012]
The present invention reduces costs by reducing the number of types of packages, has a redundant configuration including a monitoring control unit, enables high-speed system switching without complication, and expands the scale of the device to support subrack The purpose is to speed up the system switching even by expanding the device scale.
[0013]
[Means for Solving the Problems]
The redundant configuration communication apparatus of the present invention will be described with reference to FIG. 1. The redundant configuration subscriber line IF units 3-0 to 3 -n that accommodate a plurality of subscriber lines, and the intra-station IF unit 8 as well as Switch part 7 The In a communication apparatus including a main signal unit 4 including a monitoring control unit 5 and a switching control unit that performs system switching control, a monitoring control system including the monitoring control unit 5 and the switching control unit, and an in-station IF unit 8 and the main signal system including the switch unit 7 is provided as a single package, and the common unit is configured as a redundant configuration (2-1, 2-2) of the 0 system and the 1 system. Either one of system 1 System of In operation The other system is not in operation and The supervisory control unit is in operation Systematic Performs supervisory control of the main signal system and is not in operation Systematic The switching control unit is in operation. System switchover that switches the common part between active and non-operating by notification of detection of switching factor occurrence by the supervisory control part of the system It has the structure which controls.
[0014]
The in-station IF unit and the switch unit constituting the main signal system of the common part of the 0-system and the 1-system are confounded and connected via a selector, and the switching control unit performs system switching or It has a configuration for performing confounding connection switching by selector control.
[0015]
Also, a redundant subscriber line IF unit accommodating a plurality of subscriber lines, a main signal unit including an in-station IF unit and a switch unit, a monitoring control unit, and a switching control unit for controlling system switching are included. The communication apparatus has a common control unit that includes a monitoring control system including a monitoring control unit and a switching control unit, and a main signal system including an in-station IF unit, a switch unit, and a cascade IF unit. One subrack with a redundant configuration of 0 and 1 in the common part is a basic subrack as a master, and the other is a cascaded subrack as a slave. The cascade subrack system 0 and system 1 are connected to each other via the cascade IF unit, and the basic support is generated by the occurrence of a switching factor in the common part of the active system of either system 0 or system 1. Switching control of common parts during black non-operation From has the configuration and notifies the switching control unit of the common part in the non-operation of the cascade subrack, for switching the system between the basic subrack cascade subrack.
[0016]
Also, in the common part of the 0 system and 1 system that make up the subrack, the own system operation status information indicating whether the own system is operating or not operating, and the own system indicating whether the own system is in service or not in service State that stores service status information, state information including own subrack status information indicating whether the own system is a basic subrack or cascade subrack, and own system cascade number indicating a cascade subrack number at the time of basic subrack A management table is provided. The common part of the 0 system and the 1 system has a backup memory for accumulating backup data for taking over the operation state, and system identification data indicating whether the own system is the 0 system or the 1 system is stored in this backup memory. Can be configured.
[0017]
The system switching method according to the present invention includes a monitoring control system including a monitoring control unit and a switching control unit, and a common unit obtained by packaging a main signal system including an in-station IF unit and a switching unit into one package. When a switching factor occurs in the main signal system that is operating either the 0 system or the 1 system of the redundant configuration communication device having the redundant configuration, the non-operation of either the 0 system or the 1 system This includes a process of controlling the system switching by the switching control unit of the monitoring control system.
[0018]
In addition, a common part in which a monitoring control system including a monitoring control unit and a switching control unit and a main signal system including an in-station IF unit, a switch unit, and a cascade IF unit are packaged as one package is redundant between the 0 system and the 1 system. One of the configured sub-rack is a basic sub-rack and the other is a cascade sub-rack, and the cascade sub-rack system 0 and system 1 are connected to the cascade sub-rack system 0 and system 1. When a switching factor occurs in the main signal system in operation of either the 0 system or the 1 system of the redundant configuration communication device connected via the IF unit, the basic subrack system 0 and system 1 Notifying the switching control unit of the other non-operating monitoring control system of the switching factor, and notifying the switching control unit of the non-operating monitoring control system of the cascade subrack from the switching control unit The basic subrack and the casket And Dosa black is intended to include a process of switching so that the same system.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an explanatory diagram of an embodiment of the present invention, wherein 1 is a communication device, 2-1 and 2-2 are common units, 3-0 to 3-n are subscriber line IF units, and 4 is a main signal unit. Reference numeral 5 denotes a monitoring control unit, 6 denotes a clock unit, 7 denotes a switch unit, 8 denotes an in-station IF unit, and 9 denotes an extended IF unit.
[0020]
In this embodiment, the communication device 1 is divided into two types of blocks, a subscriber line IF unit and a common unit, and each type of package is mounted. That is, the communication device 1 is configured by mounting the common unit package and the subscriber line IF unit package. Further, the subscriber line IF unit has an n: 1 redundant configuration in which the subscriber line IF unit 3-0 can be switched and connected to the subscriber line IF units 3-1 to 3-n as a backup, common unit 2 -1 and 2-2 show the case of a 1: 1 redundant configuration, and the number of package types is smaller than that of the conventional example, so that the cost can be reduced.
[0021]
The common units 2-1 and 2-2 illustrate the configuration including the main signal unit 4, the monitoring control unit 5, and the clock unit 6, and the switching control without illustration of the monitoring control unit 5 and the clock unit 6. If the configuration including the unit is a monitoring control system, the configuration including the switch unit 7, the in-station IF unit 8, and the extended IF unit 9 is the main signal system. In this case, since the common units 2-1 and 2-2 have a redundant configuration, the monitoring control unit 5 also has a redundant configuration in the same manner as the clock unit 6. Each of the monitoring control units 5 of the redundant configuration common units 2-1 and 2-2 performs a monitoring process of the main signal unit 4 in a common unit in operation for processing the main signal, and is not in operation. The monitoring control unit 5 of the common unit performs only the minimum necessary processing. However, the switching control unit (not shown) controls the system switching when a switching factor is generated due to a failure of the main signal unit 4 in operation. Is what you do. Therefore, since the system switching can be controlled regardless of the monitoring process, the system switching can be performed quickly.
[0022]
The information communicated between the common parts 2-1 and 2-2 of the 0 system and the 1 system includes, for example, own system common part mounting information, own system common part failure information, as shown in FIG. , Failure notification to other system common unit, own system common unit operation information, own system common unit status notification, other system common unit reset notification, own system common unit interrupt notification, Can recognize the state between each other.
[0023]
Also, between the common units 2-1 and 2-2, for example, as shown in FIG. 3, the selector 11 provided in the intra-office IF unit 8 of the common units 2-1 and 2-2 and the subscriber line IF unit 3 are connected. Switching can be performed using the selector 13 provided. That is, the selector 13 switches and connects the active (ACT) side of the common units 2-1 and 2-2 of the 0-system and the 1-system to the subscriber line IF unit 3, and the selector 11 The switching connection of the switch unit 7 between the own system and the other system can be performed.
[0024]
In addition, the common units 2-1 and 2-2 of the 0 system and the 1 system can be quickly switched as a hot standby configuration, for example, as shown in FIG. Is stored in the nonvolatile memory 15 every time the contents of the in-device setting data, in-device state holding data, etc. are updated under the control of the processor 14 (CPU), etc. This is a backup of information to make it possible. That is, the nonvolatile memory 15 functions as a backup memory.
[0025]
5A and 5B are explanatory diagrams of the system switching process. FIG. 5A shows the system switching process performed by the conventional redundant configuration monitoring control unit, and FIG. 5B shows the system switching process according to the embodiment of the present invention. In FIG. 5A, the common units 2-1 and 2-2 in the redundant configuration of the 0 system and the 1 system use the common system 2-1 of the 0 system as the active system (in operation) and the 1 system. When the common unit 2-2 is a standby system (not in operation), the monitoring control unit of the common unit 2-1 in the active system (in operation) is a setting / control interface unit from an external higher-level operation system. The OpS-IF unit, the intra-office IF unit, the switch unit, and the switching control unit that controls the system switching are monitored at a constant cycle. That is, the portion indicated by the bold line is in operation. In this case, the monitoring controller gives priority to the monitoring process. Therefore, if a switching factor due to a failure or the like occurs during the monitoring process, the process proceeds to the switching process after the predetermined monitoring process to control the switching control unit, and the process of switching from the common unit 2-1 to the common unit 2-2 is performed. Do. That is, even if the common unit including the monitoring control unit has a redundant configuration, the system switching process cannot be immediately performed due to the occurrence of a system switching factor.
[0026]
On the other hand, in the embodiment of the present invention shown in FIG. 5B, the operation of the common unit 2-1 in the active system (in operation) is the case shown in FIG. However, the switching control unit of the common unit 2-1 is not in a state for performing the switching process. On the other hand, the monitoring control unit, the OpS-IF unit, the intra-office IF unit, and the switch unit in the common unit 2-2 of the standby system (not in operation) perform only the minimum necessary processing, and the switching control unit As shown by a bold line, the switching control operation corresponding to the active system (in operation) is possible. When a switching factor such as a failure occurs in the main signal unit of the active system (in operation), the switching control unit of the common unit 2-2 in the standby system (not in operation) is notified. Thereby, the switching control unit of the common unit 2-2 can immediately execute the system switching process. In other words, due to the occurrence of a switching factor in the active system (in operation), the supervisory control unit in the standby system (not in operation) does not perform monitoring processing, so the switching control unit is controlled to execute system switching processing at high speed. can do.
[0027]
6A and 6B are explanatory diagrams of the startup process, where FIG. 6A shows an example of a conventional process, and FIG. 6B shows an embodiment of the present invention. In FIG. 6A, when the 0 system and the 1 system are started up simultaneously, it is necessary to determine which one is the active system. First, referring to the backup data, It is determined whether it is a system ACT (Active; in operation) or not (A1). If it is not a local system ACT, it is referred to the backup data and is a system SBY (Stand-By: not in operation). (A2), if it is not the other system SBY, the system is started up as the own system SBY.
[0028]
In the case of the own system ACT with reference to the backup data, it is determined whether or not it is another system ACT (A3). In the case of another system ACT, it is determined whether or not the local system data is new with respect to the backup data (A4). Then, the above-described processing is performed again with reference to the newer backup data.
[0029]
On the other hand, in the embodiment of the present invention shown in FIG. 6B, in the case of simultaneous start-up of both the 0 system and the 1 system, the system identification of the 0 system or not is made together with the backup data. Data is set in the backup memory in advance, and the system identification data set in the backup memory is referred to determine whether or not the own system is the 0 system. If the own system is not the 0 system, SBY (standby system) Start up, and if the own system is the 0 system, the ACT (active system) is started. That is, it is possible to quickly start up as compared with the start-up process shown in FIG.
[0030]
FIG. 7 is an explanatory diagram of the common part entanglement connection. The selectors 21 and 22 are provided in the switch part 7 of the 0-system common part 2-1 and the 1-system common part 2-2, and the 0-system switch part 7 is connected. On the other hand, the selector 21 is used to switch and connect to either the 0-system in-station IF unit 8 or the 1-system in-station IF unit 8, and the 1-system switch unit 7 is connected to the system 1 through the selector 22. A confounding connection configuration for switching connection to either the 0-system in-station IF section 8 or the 1-system in-station IF section 8 is shown. Then, the switching connection is performed for the confounding connection, with the occurrence of a failure in either one or both of the local IF unit 8 and the switch unit 7 as a switching factor occurrence. Reference numeral 10 denotes an OpS-IF unit that receives setting / control information from an external higher-level operation system OpS. The entangled connection configuration shown in FIG. 3 can also be applied.
[0031]
FIG. 8 is an explanatory diagram of a system switching configuration. As shown in FIG. 7, a case where confounding connections are made between common units is shown, 30 is a higher-level operation system (NE-OPS), 31 is a station-side facing device, 32 ₀ , 32 ₁ Is a common part which is a package, 33 is a single or a plurality of subscriber line packages corresponding to the subscriber line IF part, 34 ₀ , 34 ₁ Is the main signal system, 35 ₀ , 35 ₁ Is the supervisory control system, 36 ₀ , 36 ₁ Is the in-office IF section, 37 ₀ , 37 ₁ Includes the above-described switch part and selector, etc. ₀ , 38 ₁ Is a subscriber line package interface unit, 39 ₀ , 39 ₁ Is the monitoring control unit, 40 ₀ , 40 ₁ Is a switching control unit, 41 ₀ , 41 ₁ Indicates backup memory. This backup memory 41 ₀ , 41 ₁ Corresponds to the nonvolatile memory 15 in FIG.
[0032]
The main signal between the station-side facing device 31 and the subscriber line package 33 is a common portion 32 of the 1 system of the thick line path. ₁ In-office IF section 36 ₁ And common part 32 of the 0 system ₀ The interlaced part 37 ₀ And subscriber line package IF section 38 ₀ It is transmitted on the route through. In this case, each part indicated by the bold line frame is in operation (ACT) in which it mainly operates, and the corresponding other part is in non-operation (SBY).
[0033]
For example, the 0 system common part 32 ₀ Monitoring control unit 39 ₀ Performs monitoring and control of each unit in accordance with the setting / control from the higher-level operation system 30. ₁ Monitoring control unit 39 ₁ Performs the minimum necessary operation as shown in FIG. However, the 1-system switching control unit 40 ₁ Is a state in which the switching operation is possible. ₀ Due to the occurrence of a switching factor due to a failure such as a ₁ Is the main signal system 34 as shown by the thick arrows. ₀ , 34 ₁ It is possible to control the system switching by controlling each part of the system. In-station IF unit 36 ₁ When a switching factor occurs due to a failure or the like, the switching control unit 40 ₁ The in-station IF unit 36 is controlled by ₁ And the main signal system 34 ₀ In-office IF section 36 ₀ And the in-station IF unit 36 ₀ And entanglement part 37 ₀ The confounding connection switching is performed.
[0034]
FIG. 9 is an explanatory diagram of system switching processing by switching factors, showing a case of a redundant configuration having an entanglement connection between common portions by the above-described entanglement portion and the like, and a configuration of a thick line frame in (A) to (D) Is in operation (ACT) and the configuration of the thin line frame is not in operation (SBY). A thick line arrow indicates a switching direction corresponding to the switching factors (1) to (4). In addition, (1) is a switching factor when a failure occurs in the supervisory control unit, the switch unit, and each other part, (2) is a switching factor when a transmission line failure or in-station IF unit fails, and (3) is a switching factor when executing a forced switching command. , {Circle over (4)} indicate switching factors at the time of package replacement.
[0035]
For example, FIG. 9A shows a case where the common part of the 0 system is in operation (ACT) and the common part of the 1 system is not in operation (SBY). If a failure occurs in the transmission line connected to the IF unit, which corresponds to the switching factor (2), for example, the entanglement unit 37 in FIG. ₁ As shown in FIG. 9B, the configuration including the monitoring control unit and the switch unit of the common unit of the 0 system and the in-station IF unit of the common unit of the 1 system are being operated (ACT). And the in-station IF section where the failure occurred is disconnected and is not in operation (SBY). In other words, the in-station IF unit of the 1-system common unit and the configuration including the monitoring control unit and the switch unit of the 0-system common unit can be put into operation (ACT) by confounding connection. In this state, when the package of the common part of system 1 is exchanged, it corresponds to the switching factor (4), so that the state shown in FIG.
[0036]
Further, in the state of FIG. 9A, the switching factor (1) at the time of failure of the 0-system monitoring control unit, the switch unit, etc. or the switching factor (3) by the forced switching command causes (C) in FIG. As shown in FIG. 2, the 0-system in-station IF unit, the 1-system monitoring control unit, and the like are switched to operating (ACT). In this state, in the case of the switching factor (1) due to a failure of the 1-system monitoring controller or the like, the switching factor (3) due to the forced switching command, or the switching factor (4) due to the package replacement, the state shown in FIG. Will return.
[0037]
Further, in the state of FIG. 9A, in the case of switching factor (4) due to package replacement, the state is switched to the state of FIG. 9D. The state shown in FIG. 9D and the state shown in FIG. 9C are switched according to the switching factor (2). Further, in the state of FIG. 9C, the state is switched to the state of FIG. 9D by the switching factor (4) due to the 0 system package replacement. Further, in the state of FIG. 9D, the switching factor is switched to the state of FIG. 9B by the switching factors {circle around (1)} and {circle around (3)}, and the switching factor in the state of FIG. The state is switched to the state shown in FIG. 9D by 1 ▼, 3), 4). Therefore, the main signal processing can be continued with four configurations by switching the confounding connection between the 0 system and the 1 system according to the switching factor.
[0038]
FIG. 10 is an explanatory diagram of the cascade connection configuration according to the embodiment of the present invention, and shows an embodiment in which expansion is possible in response to subrack and system switching of a redundant configuration can be performed at high speed. In the figure, 50 is a basic subrack, 51 and 52 are additional cascade subrack, 53 ₀ , 53 ₁ , 54 ₀ , 54 ₁ 55 ₀ 55 ₁ Is the common part of the 0 and 1 systems, 56 ₀ , 56 ₁ Is the IF section in the station, 57 ₀ , 57 ₁ , 58 ₀ , 58 ₁ , 59 ₀ , 59 ₁ , 60 ₀ , 60 ₁ Is the cascade IF section, 61 ₀ , 61 ₁ 62 ₀ 62 ₁ , 63 ₀ , 63 ₁ Indicates a switching control unit.
[0039]
This embodiment is a redundant configuration in which a common part consisting of a main signal system including a switch unit and the like and a monitoring control system including a monitoring control unit and a switching control unit is packaged, and the common unit is a 0 system and a 1 system. Is a subrack, one is a basic subrack as a master, and the other is a cascade subrack as a slave. The common part 53 ₀ , 53 ₁ , 54 ₀ , 54 ₁ 55 ₀ 55 ₁ Although some illustrations are omitted, they can have the same configuration including the monitoring control system and the main signal system.
[0040]
Cascade subrack 51 and 52 are connected to basic subrack 50 via a cascade IF unit corresponding to 0 system and 1 system, respectively. In addition, common part 53 of basic subrack 50 for system 0 and system 1 ₀ , 53 ₁ In-station IF section 56 ₀ , 56 ₁ Are connected to a station-side counter device (not shown) via an optical transmission line or the like, and a redundant portion of a subscriber line IF unit (shown in the figure) is common to the 0 system and 1 system in each subrack. Is omitted). It is also possible to adopt a configuration in which the packages constituting the redundant subscriber line IF unit are mounted as each subrack.
[0041]
Also, the common part 53 of the basic subrack 50 ₀ , 53 ₁ In-station IF section 56 ₀ , 56 ₁ Are connected to the station-side counter apparatus via optical transmission lines of the 0-system and the 1-system, respectively. Also, the common part 53 of the basic subrack 50 ₀ , 53 ₁ And common part 54 of cascade subrack 51 ₀ , 54 ₁ Cascade IF unit 57 between ₀ , 57 ₁ , 59 ₀ , 59 ₁ And a common portion 53 of the basic subrack 50. ₀ , 53 ₁ And cascade subrack 52 common part 55 ₀ 55 ₁ Cascade IF section 58 between ₀ , 58 ₁ , 60 ₀ , 60 ₁ And a common portion 53 of the basic subrack 50. ₀ Switching control unit 61 ₀ On the other hand, the common part 54 of the cascade subrack 51, 52 ₀ 55 ₀ Switching control unit 62 ₀ , 63 ₀ Are connected so that they can communicate with each other. ₁ Switching control unit 61 ₁ On the other hand, the common part 54 ₁ 55 ₁ Switching control unit 62 ₁ , 63 ₁ Are configured to be communicable.
[0042]
If the 0 system is in operation (ACT) for processing the main signal, as shown by the thick line, the in-station IF unit 56 ₀ Cascade IF unit 57 ₀ ~ 60 ₀ And become the operating state as the main signal system, and the 0-system monitoring control unit (not shown) performs monitoring processing of the main signal system. 1 system switching control unit 61 ₁ ~ 63 ₁ Indicates a state in which the switching control operation is possible, as indicated by a bold frame, and the 0-system switching control unit 61 ₀ ~ 63 ₀ Is in a state in which the switching control operation is not performed. When a failure occurs in the common part during operation (ACT), the 1-system switching control part 61 of the basic subrack 50 is used. ₁ To 1 of the switching control unit 62 of the cascade subrack 51, 52. ₁ , 63 ₁ To switch the system from system 0 to system 1 at high speed. After this system switching, the in-station IF section 56 of the 1 system ₁ Cascade IF unit 57 ₁ ~ 60 ₁ And become the operating state as the main signal system.
[0043]
In order to process the main signal between the plurality of subscriber lines and the network side, it is operated so that it can be identified whether it is a single subrack configuration or a configuration in which a plurality of subrack is cascaded, for example, As shown in FIG. 11, the registered contents are the communication devices 1, 2, and 3. In addition, FIG. 12 shows definitions of the single operation, basic subrack, and cascade subrack of the registered contents. For example, a subrack in which the single operation is registered is operated as a configuration having a common part of the 0 system and the 1 system as shown in FIG. 1 or FIG. The subrack to which the basic subrack is registered operates as the basic subrack 50 in FIG. 10, and the subrack to which the cascade subrack is registered operates as the cascade subrack 51 and 52 in FIG. Will do. The basic subrack operates as a master in the system, and the cascade subrack operates as a slave with respect to the basic subrack as the master.
[0044]
FIG. 13 is an explanatory diagram of inter-subrack communication. For example, the sub-rack communication is shown between the basic subrack 50 and the cascade subrack 51 shown in FIG. ₀ , 53 ₁ , 54 ₀ , 54 ₁ The status information from the other side is received by both the 0 system and 1 system ports, and a register or the like is retained. Alternatively, it is held by the state management table, and when the state information is transmitted, it is transmitted from the selected port to the other side. In addition, “1” in the operation state is in operation (ACT), “0” is in non-operation (SBY), and the failure state is “0” in the normal state or mounting state, and “1” in the failure state or not mounting. State.
[0045]
FIG. 14 is an explanatory diagram of status information during operation, showing that the 0 system is in the operating state “1”, the 1 system is in non-operating “0”, and the 0 system and 1 system are both in the normal state “0”. ing. For example, the common part 54 of the cascade subrack 51 ₀ When a failure occurs, failure state information is notified through the route shown in FIG. In the figure, reference numerals 65 and 66 denote processors (CPUs) constituting the switching control unit of the monitoring control system. That is, the occurrence of a failure in the common part during operation of the cascade subrack 51 is notified to the processor (CPU) constituting the switching control part of the common part not in operation, and the basic subrack 50 is controlled by the control of the processor (CPU). To 0 system and 1 system.
[0046]
As described above, the common part 54 of the 0 system during operation of the cascade subrack 51 (ACT) ₀ If a failure occurs, the common part 54 of system 1 that is not in operation (SBY) ₁ The processor 66 is interrupted, and by this interrupt processing of the processor 66, “1” indicating the 0 system failure state is set and notified to the 0 system and 1 system of the basic subrack 50. In this case, the basic subrack 50 that has received this failure state information receives both of the 0 system and the 1 system, and holds “1” of the 0 system failure state of the cascade subrack 51. And the common part 53 of the 1 system in non-operation (SBY) ₁ When the processor 65 of the supervisory control system is interrupted, the processor 65 executes the system switching control from the 0 system to the 1 system. That is, system switching control is performed by the switching control unit described above.
[0047]
FIG. 16 is an explanatory diagram when the operating state changes. The operating state information in which the 0 system is “1” (operating) and the 1 system is “0” (not operating) is shown in each common unit 53. ₀ , 53 ₁ , 54 ₀ , 54 ₁ In the state held in the holding means such as the register or the state management table, the operation status information is changed to “0” (non-operating) in accordance with the system switching from the monitoring control processor 65. When the 1 system is set to “1” (in operation), the common part 54 of the 0 system and 1 system of the cascade subrack 51 ₀ , 54 ₁ Each port is notified. This operation status information is sent to the common unit 54. ₀ , 54 ₁ Are stored in a holding means such as each register or a state management table, and the common unit 54 ₁ Interrupts the processor 66 of the monitoring control system. As a result, the processor 66 causes the common unit 54 ₀ , 54 ₁ The same common unit 54 as the basic subrack 50 side is controlled by switching the selector of ₁ To be in operation.
[0048]
FIG. 17 is an explanatory diagram of the state management table, showing the basic subrack 0 system and the cascade subrack 0 system. It is provided, and is provided in the monitoring control system of each system. Then, various state information of the own system and the other system is set. This state management table is used for switching due to factors such as switching commands from maintenance devices such as the host operating system at the time of start-up due to factors such as power-on or common-part reset, system switching due to common-part failure or package removal, etc. At times, it is referred to determine the status of the own system and other systems. For example, the state information can be updated under the control of the monitoring control unit.
[0049]
For example, operation status information (operating / not operating (ACT / SBY) (active / standby system)) between the own system operation status and the other system operation status, and the service between the own system service status and the other system service status Status information (in-service / out-of-service (INS); out-of-service) and in-station IF operation status information (in-service / out-of-service IF in-station IF operation status and in-system IF operation status) Medium (ACT / SBY)), failure status information (normal / abnormal) of the own system failure status and other system failure status, and failure status information (normal / abnormal) of the own board failure status and other board failure status , Startup status information of the own system startup status and other system startup status (started / not started), and mounting status information of the own system common unit mounting status and the other system common unit mounting status (mounted / not installed) Implementation) and system information (system 0 / System), the subrack status information (basic / cascade) of the local subrack status and the local subrack status, the local cascade number and the external cascade number, and the number of the extended IF section used for the cascade connection Cascade number information (No.) using the local clock input information, own system CLK input information (supplying apparatus / basic) indicating whether the clock input is supplied from the clock supply apparatus or the basic subrack, and common to the own system It also includes the own system CLK output information indicating whether or not the clock is supplied from the clock unit to the cascade subrack, and can also be set including other state information.
[0050]
In FIG. 17, the common part of the basic subrack 0 system and the cascade subrack 0 system indicates that the own system operation status information is ACT, indicating that the system is in operation (ACT). The common part of the system (other system) indicates that the other system operation status information is SBY and is in a non-operating state (SBY). The operation status information is set to ACT, and the cascade subrack system 0 is not stored because it is not connected to the in-station IF unit. Further, the in-station IF section of the first system indicates that it is not in operation (SBY) with the other-station in-station IF section operation status information as SBY. Also, the cascade number of the 0 system (own system) is set to 1 and 3, and similarly, the cascade number of the 1 system (other system) is set to 1 and 3, and as shown in FIG. A state in which the sub-racks 51 and 52 are connected is shown.
[0051]
FIGS. 18 and 19 are flowcharts when a basic subrack common unit failure occurs. When a basic subrack ACT (operation) system failure occurs (C1), basic (hereinafter, “subrack” is omitted when identification is possible). A switching factor occurs in the 0 system, and the basic both-system switching control unit notifies the occurrence of the basic switching factor (C2). It should be noted that a switching factor also occurs when the 0-system common part is removed or reset.
[0052]
According to this switching factor occurrence notification, it is determined whether or not the local service status information is in service (INS) by referring to the status management table of the basic 1 system (C3). The process proceeds to step (C5) in (C4), and in the case of non-service (OUS), the process proceeds to step (C8). Step (C4) includes steps (C5) to (C7). In step (C5), it is determined whether or not the basic 0 system is operable. As shown in the table as “Own service status → OUS, Own system failure state → Abnormal, Own board failure state → Abnormal”, the own service status information information is changed to non-service (OUS), and the own system failure status information is displayed. Is abnormally changed, and the own board failure state information is abnormally changed (C6). If the basic 0 system is inoperable, the other system service status is displayed as shown in the status management table of the basic 1 system as other system service status → OUS, other system fault status → abnormal, other board fault status → abnormal. The information is changed to non-service (OUS), the other-system failure status information is changed to abnormal, and the other-board failure status information is changed to abnormal (C7).
[0053]
If it is determined in step (C3) that the service is not in service (OUS), the failure occurrence is indicated by lamp control of the common failure part (C8), and the state management table similar to the process in step (C4) is displayed. A setting process is performed (C9), and the process ends. That is, only the status management table update process is performed in the case of system 1 failure or not installed. The lamp control indicates that the state of each part regarding normal / abnormal or ACT / SBY is controlled by lighting the lamp.
[0054]
In addition, after the processing of step (C4) in the case of local system service (INS), the basic 1 system switching control unit requests the higher level operation system OpS to disconnect the link with the basic 0 system (C10). Note that the link disconnection request is not processed when the package is removed. When a link disconnection response is received from the host operation system OpS, the link with the basic 0 system is disconnected (C11), and switching between both system switch units and lamp control are performed (C12). Then, switching of both system switch units and lamp control are performed (C13).
[0055]
Then, as shown in the state management table of the basic system 1 as own system operation state → ACT, other system operation state → SBY, the own system operation state information is changed to operating (ACT), and the other system operation information is changed to It changes to non-operation (SBY), transmits a common unit switching instruction to both cascade connection destinations, and performs lamp control (C13). Then, the cascade subrack process is started (C19), the subscriber line IF unit under the subrack is switched, and the lamp control is performed (C14). Then, with reference to the state management table of the basic 1 system, it is determined whether or not the in-station IF unit operation status information is not in operation (SBY) (C15). The state management table is updated. As shown in the status management table as IF section operating status in 1-system station → ACT, IF section operating status in 0-system station → SBY, the IF section operating status information in 1-system station is updated to operating (ACT) and The IF section operating status information is updated to non-operating (SBY) (C16), and the process proceeds to the next step (C17). If it is determined in step (C15) that the system is in operation (ACT), the process proceeds to step (C17).
[0056]
In step (C17), the basic 0 system switching control unit requests a link request with the basic 1 system to the higher level operation system OpS, and receives a link response from the higher level operation system OpS. Is set (C18), and the process ends.
[0057]
FIG. 20 shows a flowchart of the cascade subrack processing, and it is determined whether or not a common part switching instruction from the basic 1 system is received in the cascade subrack operation due to the occurrence of the basic subrack ACT system failure (D1). When received, the process proceeds to step (D2). This cascade subrack switching process corresponds to the process based on the start of the cascade subrack process in step (C19) of FIG. 19, and refers to the state management table of the cascade 1 system, and the own service state information is in service (INS ) Or not (D3), and in the case of non-service (OUS), the lamp control of the common unit is performed (D10), and the state management table of the cascade 0 system is shown as own system service state → OUS Then, the self-service status information is updated to non-service (OUS) (D11), and the process ends.
[0058]
If the result of the determination in step (D3) is that the own system service status information is in service (INS), the cascade 1 system switching control unit requests the higher operation system OpS to disconnect the link with the cascade 0 system (D4). When the link disconnection response is received from the operation system OpS, the link with the cascade 0 system is disconnected (D5). Then, as shown in the state management table of the cascade 1 system as the own system operation state → ACT, the other system operation state → SBY, the other system operation state information is not operated while the own system operation state information is in operation (ACT). The lamp is updated to medium (SBY) and the lamp control is performed (D6). Next, switching and lamp control of the subscriber line IF section under its own subrack are performed (D7), and a link request with the cascade 1 system is performed from the cascade 0 system switching control section to the higher-level operation system OpS (D8). A link response to this is received, a link with the cascade 1 system is set (D9), and the process is terminated.
[0059]
21, 22, and 23 are explanatory diagrams when a basic subrack switching factor is generated. The same reference numerals as those in FIG. ₀ , 70 ₁ 74 ₀ 74 ₁ , 77 ₀ , 77 ₁ Is the switch part, 71 ₀ , 71 ₁ , 75 ₀ , 75 ₁ , 78 ₀ , 78 ₁ Is a monitoring control unit, 72 ₀ , 72 ₁ Is the IF section in the office, 73 ₀ 73 ₁ , 76 ₀ , 76 ₁ 79 ₀ 79 ₁ Indicates an OpS-IF part.
[0060]
In the case where the inside of the thick line frame in FIG. 21 is operating (ACT), that is, the 0-system common part 53 ₀ , 54 ₀ 55 ₀ Is in operation (ACT) and is not in operation (SBY). ₁ , 54 ₁ 55 ₁ Switching control unit 61 ₁ 62 ₁ , 63 ₁ When the switching factor occurs in the basic subrack 50 in the state where only the operation is in progress, the operation indicated by the following parentheses in the order and path of the numbers in parentheses in FIGS. Is done.
[0061]
(1). Common part 53 of basic subrack 50 ₀ When a switching factor such as occurrence of a failure, common part package removal, reset, or the like occurs, the switching factor of the 0-system and 1-system switching controller 61 ₀ , 61 ₁ To the switching control unit 61 ₀ , 61 ₁ Detects this. The 0-system common part 53 ₀ 1 system switching control unit 61 ₁ Detects the switching factor.
(2). The service status of the 1st system of the basic subrack 50 is set, for example, as shown in FIG. 17 (this status management table can be provided in the monitoring control system of the common unit. To see if it can be switched. In the case of non-service (OUS), only lamp control and state management table update are performed.
[0062]
(3). Basic subrack 50 switching control unit 61 between system 0 and system 1 ₀ , 61 ₁ Updates the state management table and performs lamp control when various factors including switching factors occur. When the contents of the state management table corresponding to the 0 system of the basic subrack 50 are updated, the contents corresponding to the other systems in the 1 state management table of the basic subrack 50 are updated. In this case, when the 0-system operation of the basic subrack 50 is impossible or when the package is removed, the 1-system switching control unit 61 of the basic subrack 50 is selected. ₁ However, by setting the contents corresponding to the other system in the state management table, the switching process can be normally executed even when the other system cannot be operated.
(4). 1 system switching control unit 61 of basic subrack 50 ₁ Sends a request for disconnection of the link to the 0 system of the basic subrack 50 to the higher-level operation system OpS. ₀ To send through. The 0-system common part 53 ₀ This process is omitted in the case of removing the package.
[0063]
(5). When the link disconnection response is received from the host operation system OpS, the link with the 0 system is disconnected.
(6). The switch unit 70 is in the order of 1-system and 0-system. ₁ , 70 ₀ And lamp control. The above shows the processing in FIG.
[0064]
(7). Basic subrack 50 system 0 switching control unit 61 ₀ Updates the state management table and transmits a common unit switching instruction to the cascade connection destination while the system 1 operating state is in operation (ACT) and the system 0 operating state is not in operation (SBY). . That is, the common part 53 of the basic subrack 50 ₁ Is in operation (ACT) as indicated by a bold line, and is instructed to the cascade connection destination.
(8). Further, for the subscriber line IF unit, the basic subrack 50 is not shown, for example, the selector 13 shown in FIG. 3 is controlled to switch the connection between the common units of the 0 system and the 1 system, and the lamp Take control.
[0065]
(9). Only when the in-station IF operation status information in the status management table of the system 1 of the basic subrack 50 is not in operation (SBY), the switching of the in-station IF section is executed in accordance with the APS (Automatic Protection Switch) specification, and the switching process At the time of execution, the in-station IF section operation status information is updated and lamp control is performed (only for basic subrack). That is, by switching the in-station IF unit only when necessary, it is possible to suppress the influence of a failure inside the apparatus on the outside.
[0066]
(10). Regardless of the progress of the switching process of the cascade subrack, the switching control unit 61 of the 0 system of the basic subrack 50 ₀ Makes a link request to the higher-level operation system OpS with the system 1 of the basic subrack 50.
(11). Based on the link response from the higher-level operation system OpS, a link is made with the system 1 of the basic subrack 50, and the switching controller 61 ₀ Can quickly transition to a state where switching control is possible.
[0067]
In the cascade subrack 51, 52, as shown in FIGS. 22 and 23, the following processes (7), (9) to (15) are performed. That is,
(7). Switch control unit 62 for the cascade 0 and 1 systems of the cascade subracks 51 and 52 ₀ 62 ₁ , 63 ₀ , 63 ₁ Is a common part 53 of the basic subrack 50 ₁ The common part switching instruction is received.
(9). It is checked whether or not the switching operation is possible with reference to the service status of the first system of the cascade subrack 51 and 52. In the non-service state (OUS), only the 0 system lamp control of the cascade subrack 51 and 52 and the update of the state management table are performed.
[0068]
(10). 1 system switching control unit 62 of cascade subrack 51, 52 ₁ , 63 ₁ Sends a link disconnection request to the higher-order operation system OpS to the 0 system of the cascade subrack 51, 52, and the OpS-IF unit 76 ₀ 79 ₀ To send out.
(11). When a link disconnection response to the link disconnection request is received, the link is disconnected with the 0 system.
[0069]
(12). 1 system switching control unit 62 of cascade subrack 51, 52 ₁ , 63 ₁ Performs the lamp control by updating the state management table so that the operation status information of the own system becomes ACT and the operation status information of the other system becomes SBY.
(13). Lamp control is performed by switching the subscriber line IF under its own subrack in the same manner as in the process (8) described above.
[0070]
(14). Switch control unit 62 of cascade subrack 51, 52 of 0 system ₀ , 63 ₀ As shown in FIG. 23, the OpS-IF unit 76 is connected to the higher-level operation system OpS. ₁ 79 ₁ The link request with the system 1 of the cascade subrack 51, 52 is transmitted via
(15). A link response to the link request is received, and the system is linked with the cascade subrack 51, 52 system.
[0071]
As described above, the switching controller on the non-operating (SBY) side is in a state of communicating with each other as shown in FIG. 10. For example, the non-operating (SBY) side switching controller Switching controller 61 on the operating (SBY) side ₁ In the control processing, the system is switched to the 1 system, and the cascade subrack 51 and 52 are also switched from the 0 system to the 1 system. The system is connected in cascade and is in operation (ACT). Further, in this state, when the switching factor of the 1 system of the basic subrack 50 is generated, the 0 system of the basic subrack 50 and the 0 system of the cascade subrack are switched to be in operation (ACT).
[0072]
24 to 27 show flowcharts when the cascade subrack common unit fails, FIGS. 24 and 25 show operations on the basic subrack side, and FIGS. 26 and 27 show operations on the cascade subrack side. In the state in which the 0 system is in operation (ACT), when the cascade subrack is in operation (ACT), the basic subrack 0 system and 1 system are switched from the cascade subrack 1 system. Is received (E1). Hereinafter, “subrack” is omitted within a range where no confusion occurs.
[0073]
Referring to the status management table of the basic 1 system, it is determined whether or not the own system is in service (INS) (E2). If it is not in service (OUS), the process is terminated (completed). When the service is in service (INS), it is determined whether or not the own system cascade number and the other system cascade number are the same by referring to the status management table of the basic 1 system (E3). If they are different, the process ends. If they are the same, it is determined whether or not the own system failure state is set as normal in the state management table of the basic 1 system (E4).
[0074]
In this determination, if abnormal, the process is terminated. If normal, the basic 1-system switching control unit 61 is terminated. ₁ (See FIG. 21) sends a link disconnection request with the basic 0 system to the higher-level operation system OpS (E5). When a link disconnection response is received from the host operation system OpS, the link with the basic 0 system is disconnected (E6).
[0075]
And the switch part 70 with 0 system and 1 system ₀ , 70 ₁ Switching and lamp control are performed (E7). Next, as shown in the state management table of the basic 1 system as the own system operation state → ACT, the other system operation state → SBY, the own system operation state information is being operated (ACT), and the other system operation state information is not operated. Updating to medium (SBY), a common unit switching instruction is transmitted to the cascade connection destinations of the 0-system and the 1-system, and lamp control is performed (E8). Then, the cascade subrack process is started (E14), the switching of the subscriber line IF unit under the subrack and the lamp control are performed (E9), and the state management table of the basic 1 system is referred to. It is determined whether or not the operational status information of the in-station IF section is not operating (SBY) (E10).
[0076]
In the case of non-operation (SBY), the in-station IF unit is switched and the state management table is updated. As shown in 1-system-station IF section operation status → ACT, 0-system in-station IF section operation status → SBY In the status management table, the operating status information of the IF unit in the 1-system station is updated to operating (ACT) and the operating status information of the IF unit in the 0-system station is updated to non-operating (SBY) (E11). The process proceeds to step (E12). If it is determined in step (E10) that the system is in operation (ACT), the process proceeds to step (E12). In this step (E12), the switching control unit 61 for the basic 0 system. ₀ Sends a link request with the basic 1 system to the higher-level operation system OpS. When a link response to this link request is received, a link with the basic 1 system is formed (E13).
[0077]
The cascade subrack side performs processing as shown in FIGS. 26 and 27. When a switching factor occurs in the cascade 0 system, the switching control unit of both cascade systems, for example, the cascade subrack 51 in FIG. Common part 54 ₀ If a failure occurs in both systems, the switching control unit 62 of both systems ₀ 62 ₁ A switch factor notification is detected (F1). Then, it is determined by referring to the status management table of the cascade 1 system whether the own service status information is in service (INS) (F2).
[0078]
When not in service (OUS), lamp control is performed to indicate the common part of the failure occurrence (F3). When in service (INS), it is determined whether the cascade 0 system is operable (F4). If the operation is not possible, the status information of the other system is not in service (OUS), as shown in the status management table of the cascade 1 system as other system service status → OUS, other board failure status → abnormal. The other board failure status information is updated abnormally (F6). If it is operable, the status of the cascade 0 system status management table is indicated as “Own service status → OUS, own board failure status → abnormal”. The failure status information is updated abnormally (F5).
[0079]
Then, the basic subrack is notified of switching (F7), the basic switching process waiting timer is started, and it is determined whether or not the timer has timed out (F8). If timed out, the process is terminated. Then, it is determined whether or not a common part switching instruction is received from the basic 1 system (F9). If not received, the process proceeds to step (F8). If it is received, it is determined whether or not the own service status information in the status management table of the cascade 1 system is in service (INS) (F10). If it is not in service (OUS), the process is terminated. If the service is in service (INS), a request for disconnecting the link with the cascade 0 system is sent from the switching control unit of the cascade 1 system to the higher-level operation system OpS (F11).
[0080]
When the link disconnection response to the link disconnection request is received, the link with the cascade 0 system is disconnected (F12), and the state management table of the cascade 1 system is indicated as own system operation state → ACT, other system operation state → SBY. The system operation status information is updated during operation (ACT) and the other system operation status information is updated during non-operation (SBY), and lamp control is performed (F13). Then, switching and ramp control of the subscriber line IF unit under its own subrack are performed (F14), and a switching request unit from the cascade 0 system is sent to the higher level operation system OpS (F15). When a link response to this link request is received, a link with the basic 1 system is formed (F16).
[0081]
28, 29, and 30 are explanatory diagrams when a cascade subrack switching factor is generated, and the same reference numerals as those in FIG. 21 denote the same parts. In a state where the inside of the bold line in FIG. 28 is operating (ACT), that is, the 0-system common part 53 ₀ , 54 ₀ 55 ₀ Is in operation (ACT) and is not in operation (SBY). ₁ , 54 ₁ 55 ₁ Switching control unit 61 ₁ 62 ₁ , 63 _Three When a switching factor occurs in the cascade subrack 51 in the state where the switching control operation is possible, the following parenthesized numbers are shown in the order and path of the numbers in parentheses in FIGS. 28, 29, and 30. A basic subrack side operation and a cascade subrack side operation are performed.
[0082]
Basic subrack side operation
(4). In the basic 0 system and 1 system, the switching control unit 62 of the cascade 1 system is generated by the occurrence of a switching factor in the cascade 0 system. ₁ As shown in FIG. 28, the switch factor occurrence notification is received.
(5). It is determined whether or not switching is possible by referring to the state management table. When the service status of the basic system 1 is not in operation (OUS), the switching process is not executed. That is, by determining the basic subrack state with the highest priority, system inconsistencies can be prevented. The same processing is performed when the number of common parts of both systems connected in cascade is different, or when other system failure status information is abnormal.
[0083]
(6). Basic 1 system switching control unit 61 ₁ The basic 0 series OpS-IF unit 73 ₀ A request to disconnect the link with the basic 0 system is transmitted to the higher-level operation system OpS.
(7). The link disconnection response from the host operation system OpS is sent to the basic 0 system OpS-IF unit 73. ₀ Via the basic 1 system switching control unit 61 ₁ Is received, the link is broken with the basic 0 system.
[0084]
(8). Next, as shown in FIG. 29, the switching control unit 61 of the basic 1 system. ₁ The switch unit 70 of both systems ₀ , 70 ₁ Is switched in the order of 1 system and 0 system to perform lamp control.
(9). Basic 0 system switching control unit 61 ₀ Sets the status management table so that the operation status information of the own system is in operation (ACT) and the operation status information of the other system is not in operation (SBY). The common part switching instruction is transmitted. Lamp control is also performed.
[0085]
(10). Switch the subscriber line IF section under its own subrack and perform lamp control.
(11). Only when the in-station IF section operation status information of the basic system 1 status management table is not in operation (SBY), the in-station IF section is switched in accordance with the APS regulations. Update the group operation status information.
(12). Basic 0 system switching control unit 61 ₀ Transmits a link request with the basic system 1 to the higher-level operation system OpS.
(13). A link response to this link request is received and linked to the basic 1 system.
[0086]
Cascade subrack side operation
(1). As shown in FIG. 28, the common part 54 of the cascade 0 system ₀ When a switching factor occurs in the cascade, the switching control unit 54 in both cascade systems ₀ , 54 ₁ Detects this switching factor occurrence notification.
(2). With reference to the service status of the cascade 1 system, in the case of non-service (OUS) due to failure, unimplemented, etc., the status management table is updated and lamp control is performed. In the case of service (INS), the state management table is updated according to the switching factor, and lamp control is performed.
[0087]
(3). Cascade 1 system notifies the basic subrack 50, starts the basic subrack switching process wait timer, and determines that the basic subrack system cannot be switched when the timeout occurs. To match, do not execute the switching process. That is, this corresponds to the timeout in step (F8) of FIG. 26, and the subsequent processing is terminated. Thereafter, the processes (4) to (9) on the basic subrack side are performed.
[0088]
(10). As shown in FIG. 29, corresponding to the operation (10) on the basic subrack side, the common part 54 of both systems of the cascade is shown. ₀ , 54 ₁ Receives a common part switching instruction from the basic 1 system.
(11). It is checked whether the other system service status information in the cascade 0 system where the switching factor has occurred and the cascade 1 system is not in service (OUS), and the other board failure status information is set to abnormal. If it is not set, the lamp control is performed by setting “not in service” (OUS) and abnormal respectively.
[0089]
(12). Switching control unit 62 of cascade 1 system ₁ , 63 ₁ Is the OpS-IF unit 76 for the higher-level operation system OpS. ₀ 79 ₀ A link disconnection request is transmitted via.
(13). From the host operation system OpS, the OpS-IF unit 76 ₀ 79 ₀ When the link disconnection response is received via the link, the link with the cascade 0 system is disconnected.
[0090]
(14). The cascade 1 system updates the state management table so that the operation status information of the own system is in operation (ACT) and the operation status status information of the other system is not in operation (SBY), and performs lamp control.
(15). As shown in FIG. 30, the subscriber line IF unit under its own subrack is switched to perform lamp control.
(16). Switching control unit 62 of cascade 0 system ₀ , 63 ₀ Sends a link request with the cascade 1 system to the higher-level operation system OpS.
(17). A link response from the higher-level operation system OpS is received and linked to the cascade 1 system.
[0091]
31, 32, and 33 show operation flowcharts at the time of common part forced switching, and FIGS. 34, 35, and 36 are operation explanatory diagrams at the time of common part forced switching. The common part forced switching is executed by a forced switching command for switching from the 0 system to the 1 system or the 1 system to the 0 system for the common part package exchange or the like from the host operation system. 31 and 32 show the basic subrack side operation as steps (G1) to (G16), and FIG. 33 shows the cascade subrack side operation at the time of the forced switching as steps (H1) to (H15). 34, 35, and 36, the same reference numerals as those in the above-described drawings indicate the same parts, (1) to (17) indicate the operation order of each part, and the arrow direction indicates the notification direction of various information. Hereinafter, the processing steps (G1) to (G16) and (H1) to (H15) will be described in association with the operation order of (1) to (17).
[0092]
Basic subrack-side operation (see FIGS. 31, 32, 34 to 36)
(1). Basic 0 series OpS-IF unit 73 ₀ Receives a forced switching command from the higher-level operation system OpS (G1), the basic 1-system switching control unit 61 ₁ This forcible switching command is transferred (G2).
(2). Basic 1 system switching control unit 61 ₁ Receives this forced switching command (G3).
(3). Switching control unit 61 ₁ Refers to the state management table of the basic 1 system and checks whether switching is possible. That is, it is determined whether the local service status information is in service (INS) (G4). In the case of non-service (OUS), a forced switching error to the higher-level operation system OpS is displayed, and the OpS-IF unit 73 ₀ (G6).
[0093]
(4). When the own service status information is in service (INS), the basic 1-system switching control unit 61 ₁ Sends a link disconnection request with the basic 0 system to the higher-level operation system OpS, and the OpS-IF unit 73 ₀ (G5).
(5). Switching control unit 61 ₁ Sends a link disconnection response from the higher-level operation system OpS to the OpS-IF unit 73. ₀ Is received, the link with the basic 0 system is broken (G7).
(6). Switch unit 70 of both systems ₀ , 70 ₁ Are switched in the order of 1-system and 0-system, and lamp control is performed (G8).
[0094]
(7). Basic 0 system switching control unit 61 ₀ Updates the operational status information of the other system in the status management table during operation (ACT), updates the operational status information of the own system to non-operating (SBY), A switching instruction is transmitted and lamp control is performed (G9). The cascade subrack starts processing in accordance with the common part switching instruction (G16).
(8). Switching of the subscriber line IF unit under its own subrack and lamp control are performed (G10).
[0095]
(9). Basic 0 system switching control unit 61 ₀ The in-station IF unit 72 ₀ , 72 ₁ Switch.
(10). Basic 0 system switching control unit 61 ₀ Makes a link request with the first system to the higher-level operation system OpS (G11).
(11). A link response from the higher-level operation system OpS is received and linked to the basic 1 system (G12).
[0096]
(16). Basic 0 system switching control unit 61 ₀ Receives the common part forced completion signal from the cascade connection destination (G13).
(17). Basic 0 system switching control unit 61 ₀ Determines whether the common part forced switching completion signal is from the cascade 1 system registered in the state management table (G14), and when the determination is confirmed, the forced switching is completed to the higher-level operation system OpS. Send notification. (G15).
[0097]
Cascade subrack side operation (See Figs. 33, 35, and 36)
(8). Switching control unit 62 for both systems of the cascade ₀ 62 ₁ , 63 ₀ , 63 ₁ Determines whether a common unit switching instruction from the basic 1 system has been received (H1).
(9). When it is received, it is determined whether or not the own service status information is in service (INS) by referring to the cascade 1 system status management table (H2). In the case of non-service (OUS), the lamp control (H4) of the common unit and the self-service status information in the cascade 0 system status management table are updated to non-service (OUS) (H5).
[0098]
(10). When the own service status information is in service (INS), the switching control unit 62 of the cascade 1 system ₁ , 63 ₁ Sends a link disconnection request with the cascade 0 system to the higher-level operation system OpS (H3).
(11). When the link disconnection response is received from the host operation system OpS, the link with the cascade 0 system is disconnected (H6).
(12). The cascade 1 system performs lamp control by updating the own system operation status information in the status management table during operation (ACT) and the other system operation status information during non-operation (SBY) (H7).
[0099]
(13). As shown in FIG. 36, switching of the subscriber line IF unit under its own subrack and lamp control are performed (H8).
(14). Switching control unit 62 of cascade 0 system ₀ , 63 ₀ Is the OpS-IF unit 76 for the higher-level operation system OpS. ₁ 79 ₁ A link request is transmitted via (H9).
[0100]
(15). The link response from the higher-level operation system OpS is received and linked with the cascade 1 system (H10).
(16). Basic 0 system switching control unit 61 ₀ The common part forced switching completion notification is transmitted to (H11).
As described above, by inputting a forced switching command to the basic 0 system, the basic 0 system is switched to the basic 1 system, and the cascade 0 system is switched to the cascade 1 system, so that the cascade 1 system is compared to the basic 1 system. Can be operated in cascade connection.
[0101]
FIG. 37 is a flowchart of the 0-system side operation at the time of simultaneous startup of both systems, FIGS. 38 and 39 are flowcharts of the 1-system side operation at the time of simultaneous startup of both systems, and FIGS. 40 and 41, the subscript 0 indicates the 0 system, 1 indicates the 1 system, and 81 ₀ , 81 ₁ Is the common part, 82 ₀ , 82 ₁ Is the supervisory control unit, 83 ₀ , 83 ₁ Is the OpS-IF unit, 84 ₀ , 84 ₁ Are each part in the device such as the switch unit and the IF unit in the station, 85 ₀ , 85 ₁ Is in-device memory, 86 ₀ , 86 ₁ Indicates a backup memory, and 87 indicates a subscriber line IF unit.
[0102]
The operation sequence (1) to (16) in FIGS. 40 and 41 and steps (J1) to (J15), (K1) to (K15), (L1) to (L5) in FIGS. And will be explained.
[0103]
(1). Turn on the power or insert a package (J1), (K1).
(2). Monitoring control unit 82 ₀ , 82 ₁ Is started (J2), (K2), the own system startup state information in the state management table is set to startup (J3), (K3), and lamp control is performed.
(3). Common part 81 ₀ , 81 ₁ (J4), (K4).
[0104]
(4). The startup method is determined with reference to the state management table (J4) and (K5).
(5). The system 1 sets a timer (K6), and determines whether the system 0 has risen or not based on the presence or absence of a timeout (K7). In the case of timeout, the common part 81 of system 1 ₁ Is established as in operation (ACT) (K14). This start-up process can be the same as the processes in steps (J6) to (J14) in FIG. If not timed out, it is determined whether or not a start-up completion notification from the 0 system has been received (K8).
[0105]
(6). System 0 is its own backup memory 86 ₀ The data in the device memory 85 ₀ (J5).
(7). The data is uploaded from the established subscriber line IF section 87 under its own subrack, and the in-device memory 85 ₀ The data is updated and the data is downloaded to the inactive subscriber line IF unit 87. It is determined whether or not the processing for the number of subscriber line IF units 87 subordinate to the own subrack has not been completed (J7). If not completed, whether the subscriber line IF unit 87 under the subrack has been started up. (J8), and if it has been started, the in-device memory 85 ₀ The data of the subscriber line IF unit 87 is uploaded to the network (J9). ₀ Then, the data is downloaded to the subscriber line IF unit 87 (J10), and the process proceeds to step (J7).
[0106]
(8). As a result of the determination in the step (J7), when the processing is completed, the own system (0 system) operation status information in the own system status management table is updated to in operation (ACT), and lamp control is performed (J11).
(9). The own system startup state information in the 0 system status management table is started, and the own service status information is updated to in service (INS) (J12).
[0107]
(10). 0-system monitoring control unit 82 ₀ Sends a link request to the higher-level operation system OpS (J13).
(11). A link response from the higher-level operation system OpS is received and linked (J14), and the start-up completion and the operating state (ACT) are notified to the common part of the other system (J15).
[0108]
(12). The 1-system receives the 0-system startup completion notification and refers to the state management table to determine whether or not the 0-system is normally operated (K9). ₁ Is set up in operation (ACT) (K15). The start-up process in this case can be the same as the processes in steps (J6) to (J14) in FIG. In normal operation, the 0-system backup memory 86 ₀ To 1 system backup memory 86 ₁ Data is copied to (K10).
(13). 1 system is own backup memory 86 ₁ Data in the device memory 85 ₁ (K11).
[0109]
(14). The first system sets the operation status information of its own system to the status management table as non-operating (SBY), and performs lamp control (K12).
(15). The first system sets its own system startup status information in the status management table to “completed” and sets its own service status information to in service (INS) (K13).
[0110]
Also, when starting up a cascade subrack, refer to the state management table to check whether the operation state information of the cascade subrack matches the operation state information of the basic subrack. Is to perform switching processing so as to match. Therefore, the cascade subrack can be started up so that it becomes the same system as the 0 system or 1 system of the basic subrack.
[0111]
The present invention is not limited to the above-described embodiments, and various additions and modifications can be made. For example, a larger number of subrack can be cascade-connected to the basic subrack in units of subrack. It is also possible to do. Also, the means for performing the switching control of the redundant configuration such as the switching control unit can be realized by various known configurations.
[0112]
【The invention's effect】
As described above, the present invention includes a common unit in which the monitoring control system including the monitoring control unit 5 and the switching control unit and the main signal system including the in-station IF unit 8 and the switch unit 7 are packaged in one package. As a redundant configuration of the 0 system and the 1 system, it is connected between the subscriber line IF unit of the redundant configuration of n: 1 and the station side counter device, and one of the common units 2-1 and 2-2 is in operation ( ACT), and when the other is not operating (SBY), the switching control unit of the non-operating (SBY) side supervisory control system controls the system switching. As a common part and a subscriber line IF part, it is possible to reduce the cost by manufacturing a package having the same configuration.
[0113]
In addition, for a supervisory control system with a redundant configuration, by using the switching control unit of the non-operating common unit to control the system switching when a switching factor occurs, control by the monitoring unit of the operating common unit is not required Therefore, there is an advantage that the system can be switched at high speed.
[0114]
In addition, the subrack including the common parts of the 0 system and 1 system can be used as a subrack, one as the basic subrack 50, and the other subracks 51 and 52 can be easily connected in units of subrack. There are advantages that are possible. Each subrack has a redundant configuration including a common part between the 0 system and the 1 system. When a switching factor occurs, the switching control part of the monitoring control system of the cascade subrack is switched by the switching control part of the monitoring control system of the basic subrack. Thus, there is an advantage that the system of the basic subrack and the cascade subrack can be made the same, and the system switching can be speeded up.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of an embodiment of the present invention.
FIG. 2 is an explanatory diagram of common unit communication information.
FIG. 3 is an explanatory diagram of a common unit switching configuration;
FIG. 4 is an explanatory diagram of a backup data storage configuration.
FIG. 5 is an explanatory diagram of a system switching process.
FIG. 6 is an explanatory diagram of start-up processing.
FIG. 7 is an explanatory diagram of common part entanglement connection;
FIG. 8 is an explanatory diagram of a system switching configuration.
FIG. 9 is an explanatory diagram of a system switching process due to a switching factor.
FIG. 10 is an explanatory diagram of a cascade connection configuration according to the embodiment of this invention.
FIG. 11 is an explanatory diagram of registered contents.
FIG. 12 is an explanatory diagram of definitions of registered contents.
FIG. 13 is an explanatory diagram of inter-subrack communication.
FIG. 14 is an explanatory diagram of status information during operation.
FIG. 15 is an explanatory diagram when a failure occurs.
FIG. 16 is an explanatory diagram when an operation state changes.
FIG. 17 is an explanatory diagram of a state management table.
FIG. 18 is a flowchart when a basic subrack common unit fails.
FIG. 19 is a flowchart when a basic subrack common unit fails.
FIG. 20 is a flowchart of cascade subrack processing.
FIG. 21 is an explanatory diagram when a basic subrack switching factor occurs.
FIG. 22 is an explanatory diagram when a basic subrack switching factor occurs.
FIG. 23 is an explanatory diagram when a basic subrack switching factor occurs.
FIG. 24 is a flowchart when a cascade subrack common unit fails.
FIG. 25 is a flowchart when a cascade subrack common unit fails.
FIG. 26 is a flowchart when a cascade subrack common unit fails.
FIG. 27 is a flowchart when a cascade subrack common unit fails.
FIG. 28 is an explanatory diagram when a cascade subrack switching factor occurs.
FIG. 29 is an explanatory diagram when a cascade subrack switching factor occurs.
FIG. 30 is an explanatory diagram when a cascade subrack switching factor occurs.
FIG. 31 is an operation flowchart at the time of common part forced switching.
FIG. 32 is an operation flowchart at the time of forced switching of a common unit.
FIG. 33 is an operation flowchart for common part forced switching;
FIG. 34 is an explanatory diagram of an operation during forced switching of a common unit.
FIG. 35 is an operation explanatory diagram when a common part is forcibly switched.
FIG. 36 is an explanatory diagram of an operation at the time of forced switching of a common unit.
FIG. 37 is a flowchart showing an operation of the 0 system when both systems are started up simultaneously.
FIG. 38 is a flowchart showing the operation of the first system when both systems are started up simultaneously.
FIG. 39 is a flowchart showing the operation of the first system when both systems are started up simultaneously.
FIG. 40 is an explanatory diagram of operations at the time of simultaneous startup of both systems.
FIG. 41 is an operation explanatory diagram when both systems are started up simultaneously;
FIG. 42 is an explanatory diagram of a communication system.
FIG. 43 is an explanatory diagram of a conventional communication device.
[Explanation of symbols]
1 Communication device
2-1 and 2-2 common part
3-0 to 3-n subscriber line IF section
4 Main signal section
5 Monitoring and control unit
6 Clock part
7 Switch part
8 Office IF section
9 Extended IF section

Claims (7)

Communication device comprising a subscriber line IF unit redundant accommodating a plurality of subscriber lines, a main signal section including the station IF section and a switch unit, a monitoring control unit, and a switching control unit for controlling the switching system In
A monitoring control system including the monitoring control unit and the switching control unit, and a common unit in which a main signal system including the in-station IF unit and the switch unit is packaged,
The common part has a redundant configuration of the 0 system and the 1 system,
The one of the 0 system and the 1 system is in operation, the other system is in non-operation, and the monitoring control unit of the operating system is configured to monitor and control the main signal system of the operating system was carried out, wherein the switching control unit of the system in the non-operational, the notification of the switching event occurs detection by the monitor control unit of the system during the operation, switching the common part of the in the non-operational and in the operational A redundant configuration communication device having a configuration for performing system switching control. Common portion between the 0-system and 1-system are between the station IF section and the switch unit constituting the main signal system has a configuration in which entangled connected via the selector, the switch control unit, 2. The redundant configuration communication according to claim 1, further comprising: a system switching or a switching of the confounding connection by controlling the selector in accordance with a notification of switching factor occurrence detection by the monitoring control unit of the operating system. apparatus. Communication device comprising a subscriber line IF unit redundant accommodating a plurality of subscriber lines, a main signal section including the station IF section and a switch unit, a monitoring control unit, and a switching control unit for controlling the switching system In
A monitoring control system including the monitoring control unit and the switching control unit; and a common unit in which a main signal system including the in-station IF unit, the switch unit, and the cascade IF unit is packaged,
One of the subrack with the redundant configuration of the 0 system and 1 system as the common part is a basic subrack as a master, and the other is a cascade subrack as a slave. against it, the cascade subracks 0-system and 1-system was connected via the cascade iF section to each other, respectively, the monitoring of the 0-system and the common unit of either one of the system in operation with one system by switching factor generation detection by the control unit, the notification from the switching control unit of the common part of the system during non-operation of the basic subrack to the switching control unit of the common part of the system during non-operation of the cascade subrack A redundant configuration communication device characterized by having a configuration for performing system switching between the basic subrack and the cascade subrack.   In the common part between the 0 system and the 1 system constituting the subrack, the own system operating status information indicating whether the own system is operating or not operating, and the own system indicating whether the own system is in service or not in service State that stores service status information, state information including own subrack status information indicating whether the own system is a basic subrack or cascade subrack, and own system cascade number indicating a cascade subrack number at the time of basic subrack 4. The redundant configuration communication apparatus according to claim 3, further comprising a management table.   The common part of the 0 system and the 1 system has a backup memory for accumulating backup data for taking over the operation state, and has a configuration in which system identification data at startup is stored in the backup memory. The redundantly configured communication device according to claim 1 or 4. Redundant configuration communication in which a common unit in which a monitoring control system including a monitoring control unit and a switching control unit, and a main signal system including an in-station IF unit and a switch unit are packaged in one package is configured as a redundant configuration of the 0 system and the 1 system. In the system switching method of the device ,
The main signal system of the active system of either the 0 system or the 1 system is monitored by the monitoring control unit of the operating system, and when a switching factor occurs, the 0 system and the 1 system the other one of notifies the switching control unit of the monitoring control system of the system during non-operational, system switching method characterized by comprising the step of controlling the more system switched to said switching control unit of. Redundant configuration of the 0 system and the 1 system with a common unit in which the monitoring control system including the monitoring control unit and the switching control unit and the main signal system including the in-station IF unit, the switch unit, and the cascade IF unit are packaged One subrack is a basic subrack and the other is a cascade subrack. The 0 and 1 systems of the basic subrack are the 0 and 1 systems of the cascade subrack. In the system switching method of the redundantly configured communication device connected through the unit ,
The main signal system of the active system of either the 0 system or the 1 system is monitored by the monitoring control unit of the operating system, and when a switching factor occurs, the basic subrack 0 system When the switching factor in the switching control unit of the monitoring and control system of any other system in the non-operation of the system 1 notifies the monitor control system in the non-operation of the cascade subrack from said switching control unit A system switching method comprising: notifying the switching control unit of a system of system switching and switching the basic subrack and the cascade subrack to be the same system.

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