JP2004112721A - Redundant configuration communication device and system switching method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the cost, to accelerate the system switching and to facilitate the extension of a redundant configuration communication device of which the parts are redundantly configured and a system switching method. <P>SOLUTION: A communication device 1 is composed of two kinds of a package of subscriber's line IF parts 3-1 to 3-n configured redundantly for a plurality of subscriber's lines and a package including a main signal part 4 which includes an intra-station IF part 8 and a switch part 7, a supervisory and control part 5, a clock part 6 and a switching control part as a common part, when a switching factor such as a fault occurs in the common part including a main signal system during operation of redundantly configured common parts 2-1 and 2-2 of a 0 system and a 1 system, system switching is controlled by the switching control part in the common part including a main signal system of an inactive system. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a redundant configuration communication device in which a main signal system and a supervisory control system are packaged into one to form a redundant configuration of a 0 system and a 1 system, and system switching of the redundant configuration when a switching factor occurs can be performed at high speed. And a system switching method between system 0 and system 1.
[0002]
[Prior art]
2. Description of the Related Art In various devices, a configuration is known in which two systems, a system 0 and a system 1, have a redundant configuration, one of the two systems being an active system and the other being a standby system. At the time of maintenance or the like, the standby system is switched to the active system to continue processing, and the previous active system is switched to the standby system to perform maintenance work, etc., thereby improving reliability. I have. Also, with the spread of the Internet, for example, in response to the spread of ADSL (Asymmetric Digital Subscriber Line) as a broadband, it has been demanded to improve the reliability of a subscriber communication device installed at the station side. .
[0003]
In addition, for the communication network of the system 0 and the system 1 which can operate independently, a common part for the subscriber circuit of the system 0 and the system 1 is provided, and the subscriber circuit is provided in accordance with the system switching signal from the communication network. On the other hand, there is known a system switching control circuit that switches and connects any one of the subscriber circuit common units of system 0 and system 1 to prevent malfunction of the subscriber circuit at the time of system switching (for example, Patent Document 1). reference).
[0004]
The transmission line in the communication system also has a redundant configuration of system 0 and system 1, and a switching means for switching the transmission line for each predetermined section when a failure occurs is provided. In order to prevent the switching to the standby system from causing the system switching in the subsequent section, malfunction information is sent to the standby transmission line by sending alarm information as a pseudo-failure state and controlling the redundant system switching. There is known a system for preventing such a problem (for example, see Patent Document 2).
[0005]
As a communication system, for example, a configuration shown in FIG. 42 is generally used. 100 is a station apparatus, 101 is a user home apparatus, 102 is a modem, 103 is the Internet, 104 is a public network, and 105 is a communication apparatus (subscriber). Line terminal equipment), 106 is a router, 107 is an exchange, and OpS is an upper-level operation system.
[0006]
For example, when the above-mentioned ADSL is applied, the data system communicates on the transmission path between the terminal of the user home device 101 via the modem 102, the communication device 105 of the station device 100, and the router 106 via the Internet 103. In the voice system, a telephone call is made from the telephone of the user home device 101 via the communication device 105 of the station device 100 and the exchange 107 to the public network 104.
[0007]
In such a communication system as well, a configuration is adopted in which the main part of the station device 100 is configured as a redundant configuration so that the service can be continuously provided by switching to the standby system even when a failure occurs. For example, the communication device 105 of the station device 100 generally has a configuration illustrated in FIG. 43. 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 monitoring control. , 116-1 and 116-2 are clock sections, 117-1 and 117-2 are switch sections, and 118-1 and 118-2 are intra-office IFs for connecting to the router 106 and the exchange 107 in FIG. Interface units 119-1 and 119-2 indicate extended IF (interface) units.
[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. Blocks other than the block 115 are redundantly configured. In this case, one subscriber line IF unit 113-0 is set as a spare for the n subscriber line IF units 113-1 to 113-n, and this spare subscriber line IF unit 113-0 is used as another. An n: 1 redundant configuration in which switching connection is enabled by a switching unit (not shown) with respect to the subscriber line IF unit, and switch units 117-1 and 117-2 constituting the main signal unit 114 and an intra-office IF unit The 118-1 and 118-2 and the extension IF units 119-1 and 119-2 have a 1: 1 redundant configuration, and the clock units 116-1 and 116-2 for supplying clock signals to the respective units have a 1: 1 redundancy configuration. The case of a redundant configuration is shown.
[0009]
The monitor control unit 115 performs processing such as setting, control, and collection of fault information for the main signal unit 114. The monitor control unit 115 is physically independent of the main signal unit 114, and the fault of the monitor control unit 115 is , The main signal section 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 them, and a monitoring process is performed, and switching is controlled by communicating with each other. , The quick switching is not easy and the cost increases.
[0010]
[Patent Document 1]
JP-A-6-335036 (pages 5 and 6, FIGS. 1 and 2)
[Patent Document 2]
JP-A-10-117183 (page 2, page 3, FIGS. 1 and 3)
[0011]
[Problems to be solved by the invention]
In the above-mentioned communication device, there is a demand for speeding up system switching for a redundant configuration, as well as miniaturization and cost reduction. Further, in order to increase the number of subscriber lines accommodated, it is required to have expandability. However, the above-described conventional communication device is configured by mounting packages corresponding to at least four types of blocks, thus requiring a large amount of space and increasing the cost due to the production of various types of packages. Further, when the redundant configuration is applied to the monitoring control unit 115, as described above, transmission and reception of control information between the redundant configurations is performed, and control of system switching is performed. There is a problem that it is difficult to perform high-speed system switching at the time of occurrence.
[0012]
The present invention reduces the cost by reducing the number of types of packages, has a redundant configuration including a monitoring control unit, enables high-speed system switching without complicating the system, and expands the scale of the device for subrack. And speeding up system switching even by expanding the device scale.
[0013]
[Means for Solving the Problems]
Referring to FIG. 1, a redundantly configured communication apparatus according to the present invention includes a redundantly configured subscriber line IF unit 3-0 to 3-n accommodating a plurality of subscriber lines, an intra-office IF unit 8, and a switch unit. In a communication device including a main signal unit 4 including a monitoring control unit 7, a monitoring control unit 5, and a switching control unit for controlling system switching, a monitoring control system including the monitoring control unit 5 and the switching control unit; It has a common unit in which the main signal system including the intra-office IF unit 8 and the switch unit 7 is packaged in one package, and this common unit has a redundant configuration (2-1, 2-2) of the system 0 and the system 1; The supervisory control unit of the supervisory control system in the common unit including the active main signal system of either the 0 system or the 1 system performs monitoring control of the active main signal system, and performs the non-operating main signal system. The switching control unit of the monitoring control system in the common unit including the system is configured to control the system switching by the occurrence of the switching factor of the operating main signal system. To.
[0014]
It has a configuration in which an intra-station IF unit and a switch unit constituting a main signal system of a common unit of the system 0 and the system 1 are connected in a confounding manner via a selector. It has a configuration for performing confounding connection switching by selector control.
[0015]
Also includes a subscriber line IF unit having a redundant configuration accommodating a plurality of subscriber lines, a main signal unit including an intra-office IF unit and a switch unit, a monitoring control unit, and a switching control unit for controlling system switching. The communication device has a common unit in which a supervisory control system including a supervisory control unit and a switching control unit and a main signal system including an intra-office IF unit, a switch unit, and a cascade IF unit are packaged in one. One of the subracks in which the common unit has a redundant configuration of the system 0 and the system 1 is a basic subrack serving as a master, and the other is a cascade subrack serving as a slave. , The system 0 and the system 1 of the cascade subrack are connected to each other via a cascade IF unit, and a switching factor is generated in a common part of the operating system of the system 0 and the system 1 to generate the basic system. Black common part switching control during 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 constituting the subrack, the self-system operation status information indicating whether the self-system is operating or not operating, and the self-system indicating whether the self-system is operating or not serviced A state that stores service state information, state information including own system 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 the basic subrack. Provide a management table. The common part of the system 0 and the system 1 has a backup memory for storing backup data for taking over the operation state, and stores system identification data indicating whether the system is the system 0 or the system 1 in the backup memory. It can be set as the structure made.
[0017]
A 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 in which a main signal system including an intra-office IF unit and a switch unit is packaged into one system, a 0 system and a 1 system. When a switching factor occurs in one of the operating main signal systems of either the 0 system or the 1 system of the redundant communication device having the redundant configuration, the other system of the 0 system and the 1 system is not operated. This includes a step of performing system switching control by the switching control unit of the middle monitoring control system.
[0018]
A common unit in which a supervisory control system including a supervisory control unit and a switching control unit and a main signal system including an intra-office IF unit, a switch unit, and a cascade IF unit are packaged into one package is redundantly provided for the 0 system and the 1 system. One of the configured subrack is a basic subrack, the other is a cascade subrack, and the system 0 and system 1 of the cascade subrack are cascaded with respect to the system 0 and system 1 of the basic subrack. When a switching factor occurs in one of the operating main signal systems of either the system 0 or the system 1 of the redundant communication device connected via the IF unit, the system 0 and the system 1 of the basic subrack are switched. Notifying the switching factor of one of the other non-operating monitoring control systems of the switching factor, and notifying the system switching to 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 cascade And Dosa black is intended to include a process of switching so that the same system.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is an explanatory view 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 indicates a monitoring control unit, 6 indicates a clock unit, 7 indicates a switch unit, 8 indicates an intra-office IF unit, and 9 indicates an extension IF unit.
[0020]
In this embodiment, the communication apparatus 1 is divided into two types of blocks, ie, 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.
The subscriber line IF unit has an n: 1 redundant configuration in which the subscriber line IF units 3-0 to 3-n can be switched and connected to the subscriber line IF units 3-0 to 3-n as spares, and the common unit 2 -1 and 2-2 indicate the case of a 1: 1 redundant configuration. Since the number of package types is smaller than that of the conventional example, cost can be reduced.
[0021]
Further, the common units 2-1 and 2-2 illustrate a configuration including the main signal unit 4, the monitoring control unit 5, and the clock unit 6, and the monitoring control unit 5, the clock unit 6, and the switching control not illustrated. If the configuration including the section is a monitoring control system, the configuration including the switch section 7, the intra-office IF section 8 and the extension IF section 9 becomes 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 like the clock unit 6. Each of the monitoring control units 5 of the common units 2-1 and 2-2 of the redundant configuration performs monitoring processing of the main signal unit 4 in the operating common unit that processes the main signal, and performs the non-operating operation. Although the monitoring control unit 5 of the common unit performs only the minimum necessary processing, the switching control unit (not shown) controls the system switching due to the occurrence of a switching factor due to a failure of the operating main signal unit 4 or the like. Is what you do. Therefore, system switching can be controlled irrespective of the monitoring process, so that system switching can be performed quickly.
[0022]
The information mutually communicated between the common units 2-1 and 2-2 of the system 0 and the system 1 includes, for example, self-system common unit mounting information and self-system common unit failure information as shown in FIG. And a failure notification to the other system common unit, own system common unit operation information, own system common unit state notification, other system common unit reset notification, and own system common unit interrupt notification. Thus, the state between each other can be recognized.
[0023]
Further, 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 Switching can be performed using the selector 13 provided. That is, the selector 13 switches between the active (ACT) sides of the common units 2-1 and 2-2 of the 0-system and the 1-system with respect 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]
For example, as shown in FIG. 4, the common units 2-1 and 2-2 of the 0-system and the 1-system have a non-volatile memory 15 as shown in FIG. Under the control of the processor 14 (CPU) and the like, every time the contents of the setting data in the apparatus and the state holding data in the apparatus are updated, they are stored in the nonvolatile memory 15 to take over the operation in the apparatus. The information to make it possible is backed up. That is, the nonvolatile memory 15 functions as a backup memory.
[0025]
FIGS. 5A and 5B are explanatory diagrams of a system switching process, in which FIG. 5A shows a system switching process performed by a conventional redundant configuration monitoring controller, and FIG. 5B shows a system switching process according to an embodiment of the present invention. In FIG. 5A, the common units 2-1 and 2-2 in the redundant configuration of the system 0 and the system 1 are configured such that the common unit 2-1 of the system 0 is the active system (during operation) and the system 1 is the active system. When the common unit 2-2 is set to the standby system (non-operating), the monitoring control unit of the working unit (operating) common unit 2-1 is an interface unit for setting / control 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 regular intervals. That is, the part shown by the thick 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 shifts to the switching process after the predetermined monitoring process, controls the switching control unit, and performs the process of switching from the common unit 2-1 to the common unit 2-2. Do. That is, even if the common unit including the monitoring control unit has a redundant configuration, it is not possible to immediately shift to the system switching process due to the occurrence of the 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 of the working system (in operation) is described in the case shown in FIG. However, the switching control unit of the common unit 2-1 is not in a state of 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 perform the switching control unit. Indicates a state in which the switching control operation corresponding to the active system (during operation) can be performed, as indicated by the thick line. Then, when a switching factor such as a failure occurs in the main signal unit of the active system (operating), the switching control unit of the common unit 2-2 of the standby system (operating) is notified. Thereby, the switching control unit of the common unit 2-2 can immediately execute the system switching process. That is, the monitoring control unit of the standby system (during operation) does not perform the monitoring process due to the occurrence of the switching factor of the active system (during operation), and thus controls the switching control unit to execute the system switching process at high speed. can do.
[0027]
6A and 6B are explanatory diagrams of a start-up process, in which FIG. 6A shows an example of a conventional process, and FIG. 6B shows an embodiment of the present invention. In FIG. 6A, when the system 0 and the system 1 are started up at the same time, it is necessary to determine which is the active system. It is determined whether or not it is a system ACT (Active; in operation) (A1). If it is not the system ACT, it is referred to the backup data and whether or not it is another system SBY (Stand-By; not in operation). (A2), and if it is not the other system SBY, it is started up as its own system SBY.
[0028]
If the ACT is the own ACT with reference to the backup data, it is determined whether or not the ACT is another ACT (A3). If the ACT is not the other ACT, the ACT is activated as the own ACT. In the case of the other system ACT, it is determined whether or not the data of the own system is new as 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 as to whether the system is the 0-system or not together with the backup data. Data is set in the backup memory in advance, and it is determined whether or not the own system is the 0 system by referring to the system identification data set in the backup memory. If the own system is not the 0 system, SBY (standby system) If the own system is the 0 system, the ACT (active system) is started. That is, the start-up can be performed more quickly than in the start-up processing shown in FIG.
[0030]
FIG. 7 is an explanatory diagram of the common part confounding connection. The selectors 21 and 22 are provided in the switch part 7 of the common part 2-1 of the system 0 and the common part 2-2 of the system 1 so that the switch To the 0-system intra-station IF unit 8 or the 1-system intra-station IF unit 8 via the selector 21, and to the 1-system switch unit 7 via the selector 22. A confounding connection configuration for switching connection to one of the 0-system intra-station IF section 8 and the 1-system intra-station IF section 8 is shown. Then, the occurrence of a failure in one or both of the local IF unit 8 and the switch unit 7 is set as a switching factor, and the confounding connection is switched. Reference numeral 10 denotes an OpS-IF unit that receives setting / control information from an external host operation system OpS. Further, the confounding connection configuration shown in FIG. 3 can be applied.
[0031]
FIG. 8 is an explanatory diagram of a system switching configuration, as shown in FIG. 7, showing a case where the common units are entangled and connected, 30 is a higher-level operation system (NE-OPS), 31 is a station-side device, 32 ₀ , 32 ₁ Is a common part, each of which is a package; 33 is a single or a plurality of subscriber line packages corresponding to the subscriber line IF unit; ₀ , 34 ₁ Is the main signal system, 35 ₀ , 35 ₁ Is the supervisory control system, 36 ₀ , 36 ₁ Is the intra-office IF section, 37 ₀ , 37 ₁ 38 is a confounding section that includes the above-described switch section and selector, and performs confounding connection. ₀ , 38 ₁ Is a subscriber line package interface, 39 ₀ , 39 ₁ Is a monitoring control unit, 40 ₀ , 40 ₁ Is a switching control unit, 41 ₀ , 41 ₁ Indicates a backup memory. This backup memory 41 ₀ , 41 ₁ Corresponds to the nonvolatile memory 15 in FIG.
[0032]
The main signal between the optical line terminal 31 and the subscriber line package 33 is a common line 32 of the first system of the thick line route. ₁ Intra-office IF section 36 ₁ And the common part 32 of the 0 system ₀ Confounding part 37 ₀ And subscriber line package IF unit 38 ₀ And transmitted on the path via. In this case, each unit indicated by a thick line frame is in operation (ACT) in which the main unit mainly operates, and the other corresponding unit is in operation (SBY).
[0033]
For example, the common part 32 of the 0 system ₀ Monitoring control unit 39 ₀ Performs supervision and control of each unit according to 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 switching control unit 40 of the first system ₁ Is in a state in which the switching operation is possible, and therefore, the common unit 32 of the 0 system ₀ The switching control unit 40 of the first system ₁ Is the main signal system 34 as indicated by the bold arrow. ₀ , 34 ₁ Can be controlled to control system switching. In-station IF section 36 ₁ When a switching factor occurs due to a failure of the switch, the switching control unit 40 ₁ Control, the intra-office IF section 36 ₁ And the main signal system 34 ₀ Intra-office IF section 36 ₀ And the intra-office IF unit 36 ₀ And confounding part 37 ₀ And the confounding connection is switched.
[0034]
FIG. 9 is an explanatory diagram of a system switching process based on a switching factor, and shows a case of a redundant configuration having a confounding connection between common parts by the above-described confounding unit and the like, and a configuration of a thick line frame in (A) to (D). Indicates that the operation is in operation (ACT) and the configuration of the thin line frame is in operation (SBY).
Bold arrows indicate switching directions corresponding to the switching factors (1) to (4). In addition, (1) is a switching factor at the time of failure of the monitoring control unit, the switch unit, and other units, (2) is a switching factor of a transmission line failure or an intra-station IF unit failure, and (3) is a switching factor at the time of executing a forced switching command. , (4) indicate switching factors at the time of package replacement.
[0035]
For example, FIG. 9A shows the case where the common unit of the system 0 is operating (ACT) and the common unit of the system 1 is not operating (SBY). When the failure of the transmission line connected to the IF unit occurs, it corresponds to the switching factor (2). ₁ As shown in FIG. 9B, the configuration including the monitoring control unit and the switch unit of the 0-system common unit and the intra-office IF unit of the 1-system common unit are in operation (ACT). It is assumed that the in-station IF unit in which the failure has occurred is disconnected and is in non-operation (SBY).
That is, the in-station IF unit of the common unit of the system 1 and the configuration including the monitoring control unit and the switch unit of the common unit of the system 0 can be put into operation (ACT) by confounding connection. Further, in this state, when the package of the common part of the first system is replaced, the state returns to the state of FIG.
[0036]
Further, in the state of FIG. 9A, the switching factor (1) at the time of failure of the monitoring control unit, the switch unit, etc. of the 0 system or the switching factor (3) by the forced switching command causes the switching of the FIG. As shown in (1), the in-station IF unit of system 0 and the supervisory control unit of system 1 are switched to operation (ACT). In this state, in the case of the switching factor (1) due to a failure of the monitoring and control unit of the first system, the switching factor (3) due to the forced switching command, or the switching factor (4) due to package replacement, the state shown in FIG. Will return to.
[0037]
In the case of the switching factor (4) due to the package replacement in the state of FIG. 9A, 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. Further, in the state of FIG. 9D, the state is switched to the state of FIG. 9B by the switching factors (1) and (3), and in the state of FIG. By (1), (3), and (4), the state is switched to the state of (D) in FIG. Therefore, the confounding connection between the 0 system and the 1 system can be switched according to the switching factor, and the main signal processing can be continued in four different configurations.
[0038]
FIG. 10 is an explanatory diagram of a cascade connection configuration according to an embodiment of the present invention, and shows an embodiment in which expansion can be performed for a 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 system 0 and system 1, 56 ₀ , 56 ₁ Is the intra-office IF section, 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]
In this embodiment, a common unit including 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 configured as a redundant system including 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, and can be added in subrack units. The common unit 53 ₀ , 53 ₁ , 54 ₀ , 54 ₁ , 55 ₀ , 55 ₁ Although not shown in the drawings, may have the same configuration including a monitoring control system and a main signal system.
[0040]
The cascade subrack 51 and the cascade subrack 52 are connected to the basic subrack 50 via the cascade IF unit corresponding to the 0 system and the 1 system, respectively. In addition, the common part 53 of the system 0 and the system 1 of the basic subrack 50 ₀ , 53 ₁ Intra-office IF section 56 ₀ , 56 ₁ And a station side opposing device (not shown) via an optical transmission line or the like, and a common part of system 0 and system 1 in each subrack is provided with a redundant subscriber line IF unit (shown in the drawing). Is omitted). It is also possible to adopt a configuration in which a package constituting the redundantly configured subscriber line IF unit is mounted as each subrack.
[0041]
The common part 53 of the basic subrack 50 ₀ , 53 ₁ Intra-office IF section 56 ₀ , 56 ₁ Are connected to the station-side opposing device via optical transmission lines of system 0 and system 1, respectively. The common part 53 of the basic subrack 50 ₀ , 53 ₁ Common part 54 of the cascade subrack 51 ₀ , 54 ₁ Between the cascade IF unit 57 ₀ , 57 ₁ , 59 ₀ , 59 ₁ And the common part 53 of the basic subrack 50 ₀ , 53 ₁ Of the cascade subrack 52 ₀ , 55 ₁ Cascade IF unit 58 ₀ , 58 ₁ , 60 ₀ , 60 ₁ Through the common section 53 of the basic subrack 50. ₀ Switching control unit 61 ₀ , The common part 54 of the cascade sub-rack 51, 52 ₀ , 55 ₀ Switching control unit 62 ₀ , 63 ₀ Are communicably connected to each other, and ₁ Switching control unit 61 ₁ For the common part 54 ₁ , 55 ₁ Switching control unit 62 ₁ , 63 ₁ Are communicably connected.
[0042]
Assuming that the system 0 is in operation (ACT) for processing the main signal, the intra-station IF unit 56 ₀ And the cascade IF unit 57 ₀ ~ 60 ₀ Are operating as the main signal system, and the monitoring control unit (not shown) of the 0 system performs the monitoring processing of the main signal system. Further, the switching control unit 61 of the first system ₁ ~ 63 ₁ Is in a state in which the switching control operation is enabled, as indicated by the thick line frame, and the switching control unit 61 of the 0 system ₀ ~ 63 ₀ Is in a state in which the switching control operation is not performed. When a failure occurs in the common unit during operation (ACT), the switching control unit 61 of the first system of the basic subrack 50 is activated. ₁ To the cascade sub-rack 51, 52, the one-system switching controller 62 ₁ , 63 ₁ And the system switching from the system 0 to the system 1 is executed at high speed.
After this system switching, the intra-station IF unit 56 of the first system ₁ And the cascade IF unit 57 ₁ ~ 60 ₁ Become an operation state as a main signal system.
[0043]
In order to process the main signal between a plurality of subscriber lines and the network side, it is operated so as to be able to identify a single subrack configuration or a configuration in which a plurality of subrackes are cascaded, for example, As shown in FIG. 11, the registration contents are the same as those of the communication devices 1, 2, and 3. FIG. 12 shows the definition of independent operation, basic subrack, and cascade subrack of the registered contents. For example, a subrack in which single operation is registered is operated as a configuration having a common part of the system 0 and the system 1 as shown in FIG. 1 or FIG. The subrack in which the basic subrack is registered is operated as the basic subrack 50 in FIG. 10, and the subrack in which the cascade subrack is registered is operated as the cascade subrack 51, 52 in FIG. Will do. The basic subrack operates as a master in the system, and the cascade subrack operates as a slave to the basic subrack as the master.
[0044]
FIG. 13 is an explanatory diagram of the communication between the sub-racks. For example, FIG. 13 shows the communication between the basic sub-rack 50 and the cascade sub-rack 51 shown in FIG. ₀ , 53 ₁ , 54 ₀ , 54 ₁ Between the system 0 and the system 1, the status information from the partner side is received by both ports of the system 0 and the system 1 and holding means such as a register is provided. Alternatively, when the state information is stored in the state management table and the state information is transmitted, the state information is transmitted from the selected port to the partner side. The operation state “1” is in operation (ACT), “0” is not in operation (SBY), and the failure state is “0” in the normal state or mounted state, and “1” in the failed state or not mounted. State.
[0045]
FIG. 14 is an explanatory diagram of state information at the time of operation, and shows that the system 0 is in the operation state “1”, the system 1 is in the non-operation state “0”, and the system 0 and the system 1 are in the normal state “0”. ing. For example, the common part 54 of the cascade subrack 51 ₀ In the case where a failure has occurred, failure state information is notified through the path shown in FIG. In the figure, reference numerals 65 and 66 denote processors (CPUs) constituting a switching control unit of the monitoring control system. That is, the occurrence of a failure in the common unit during operation of the cascade subrack 51 is notified to the processor (CPU) constituting the switching control unit for the non-operating common unit, and the basic subrack 50 is controlled by the processor (CPU). 0 system and 1 system.
[0046]
As described above, the 0-system common unit 54 during operation (ACT) of the cascade subrack 51 ₀ When a failure occurs in the system, the common unit 54 of the system 1 in non-operation (SBY) ₁ An interrupt is made to the processor 66, and by the interrupt processing of the processor 66, "1" indicating the 0-system failure state is set, and the 0-system and 1-system of the basic subrack 50 are notified. In this case, in the basic subrack 50 that has received this failure state information, it is received by both the system 0 and the system 1 and holds “1” in the system 0 failure state of the cascade subrack 51. Then, the non-operating (SBY) 1-system common unit 53 ₁ When the processor 65 of the monitoring control system is interrupted, the processor 65 executes system switching control from system 0 to system 1. That is, the system switching control is performed by the above-described switching control unit.
[0047]
FIG. 16 is an explanatory diagram when the operation status changes. The operation status information in which the system 0 is set to “1” (operating) and the system 1 is set to “0” (non-operating) is stored in each common unit 53. ₀ , 53 ₁ , 54 ₀ , 54 ₁ When the system is switched from the monitoring control system processor 65 in the state of being held in the holding means such as the register or the state management table, the operation state information is set to “0” (non-operating) for the system 0, When the system 1 is set to “1” (operating), the common unit 54 of the system 0 and the system 1 of the cascade subrack 51 ₀ , 54 ₁ Is notified to each port. This operation status information is transmitted to the common unit 54. ₀ , 54 ₁ Are stored in holding means such as respective registers or a state management table. ₁ Interrupt to the processor 66 of the monitoring control system. As a result, the processor 66 ₀ , 54 ₁ Of the first sub-rack 50 and the same common system 54 ₁ Is switched to be in operation.
[0048]
FIG. 17 is an explanatory diagram of the state management table, and shows the 0 system of the basic subrack and the 0 system of the cascade subrack. It is provided in the monitoring control system of each system. Then, various kinds of status information of the own system and the other system are set.
This state management table is used for starting up due to factors such as power-on or resetting of common parts, system switching due to failure of common parts or removal of packages, switching due to switching commands from maintenance equipment such as a higher-level operation system, etc. At times, it is referred to to determine the state of the own system and the other system. The status information can be updated, for example, under the control of the monitoring control unit.
[0049]
For example, the service status information of the own system operation status and the other system operation status (active / non-operating (ACT / SBY) (active / standby system)) and the service of the own system service status and the other system service status State information (In service / out of service (INS; In Service / OUS; Out of Service)) and intra-office IF operation status information of the IF section operation state in the own station and the IF operation state in another station (in operation / non-operation) Medium (ACT / SBY)), failure state information (normal / abnormal) between the own system failure state and the other system failure state, and failure state information (normal / abnormal) between the own board failure state and the other board failure state. , The start-up state information of the own system start-up state and the other system start-up state (started up / not started) Implementation), and system information (0 system / System), the subrack status information (basic / cascade) of the own system subrack state and the other system subrack state, and the number of the extension IF unit used in the cascade connection for the own system cascade number and the other system cascade number Cascade number information (No.), the own system CLK input information (supply device / basic) indicating whether the clock input is supplied from the clock supply device or supplied from the basic subrack, and shared by the own system. And the own system CLK output information indicating whether or not a clock is supplied from the clock section to the cascade subrack, and may be set to include other state information.
[0050]
In FIG. 17, the common part of the system 0 of the basic subrack and the system 0 of the cascade subrack indicates that its own system operation state information is ACT, and indicates that it is in operation (ACT), and The common part of the system (other system) uses the other system operation status information as SBY to indicate that the system is in non-operation (SBY). The unit operation state information is ACT, and nothing is stored in the cascade subrack 0 system because it is not connected to the intra-office IF unit. Further, the in-station IF section of the first system is set to SBY as the operating state information of the other-system IF section, indicating that it is not operating (SBY). Also, as shown in FIG. 10, the cascade numbers of the system 0 (own system) are 1, 3 and the cascade numbers of the system 1 (other system) are 1, 3, as shown in FIG. This shows a state in which subrack 51 and 52 are connected.
[0051]
FIGS. 18 and 19 show a flowchart when the basic subrack common part fails. When the basic subrack ACT (operation) system failure occurs (C1), the basic (hereinafter, “subrack” is omitted when identifiable). A switching factor occurs in the 0 system, and the basic dual system switching control unit notifies the occurrence of the basic switching factor (C2). It should be noted that a switching factor also occurs at the time of extracting or resetting the 0-system common unit.
[0052]
In accordance with the switching factor occurrence notification, it is determined whether the own system service status information is in service (INS) by referring to the status management table of the basic system 1 (C3). The process shifts to step (C5) in (C4), and shifts to step (C8) in the case of non-service (OUS). The step (C4) includes steps (C5) to (C7). In the step (C5), it is determined whether or not the basic 0 system is operable. As shown in the table, “own service status → OUS, own system failure state → abnormal, own board failure state → abnormal”, the own system service state information information is changed to “not in service (OUS)”, and the own system failure state information is changed. Is abnormally changed, and the own board failure state information is abnormally changed (C6).
When 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 out of service (OUS), the other system failure state information is changed to abnormal, and the other board failure state information is changed to abnormal (C7).
[0053]
If it is determined in step (C3) that the service is not being performed (OUS), the occurrence of a failure is displayed by the lamp control of the failure common unit (C8), and the same status management table as that in step (C4) is displayed. The setting process is performed (C9), and the process ends. That is, in the case of a failure of the first system or no mounting, only the update processing of the state management table is performed. Note that the lamp control indicates that the state of each unit regarding normal / abnormal, ACT / SBY, and the like is controlled by lighting the lamp and the like.
[0054]
Also, after the processing in step (C4) in the case of the own system service (INS), the basic 1 system switching control unit requests the upper operation system OpS to disconnect the link with the basic 0 system (C10). In the case of removing the package, the processing of the link disconnection request is not performed. When a link disconnection response is received from the higher-level operation system OpS, the link to the basic 0 system is disconnected (C11), and both system switches are switched and ramp control is performed (C12). Then, switching of both system switch units and lamp control are performed (C13).
[0055]
Then, as shown in the status management table of the basic system 1 as “own system operation status → ACT, other system operation status → SBY”, the self system operation status information is changed to “operation (ACT)”, and the other system operation information is changed. The status is changed to non-operation (SBY), a common unit switching instruction is transmitted to both system cascade connection destinations, and lamp control is performed (C13). Then, the cascade subrack process is started (C19), the subscriber line IF section under its own subrack is switched, and lamp control is performed (C14). Then, by referring to the status management table of the basic system 1, it is determined whether or not the operation status information in the local station IF section is not operating (SBY) (C15). Update of the state management table. The status management table updates the IF section operation status information in the 1st station to operating (ACT) as shown as “1st station IF section operation status → ACT, 0th station IF section operation status → SBY”, and The operation status information of the IF unit is updated to non-operation (SBY) (C16), and the process proceeds to the next step (C17). If it is determined in step (C15) that the device is in operation (ACT), the process proceeds to step (C17).
[0056]
In step (C17), the basic 0 system switching control unit requests the upper operation system OpS for a link request with the basic 1 system, and receives a link response from the higher operation system OpS to thereby request the basic 1 system. Is set (C18), and the process ends.
[0057]
FIG. 20 is a flowchart of the cascade subrack process. In the operation of the cascade subrack due to the occurrence of a basic subrack ACT system failure, it is determined whether or not a common unit switching instruction has been received from the basic 1 system (D1). , Upon receipt, the process proceeds to step (D2). This cascade subrack switching processing corresponds to the processing based on the start of the cascade subrack processing in step (C19) in FIG. 19, and refers to the state management table of the cascade 1 system, and the own system service state information indicates that the service is in service (INS). ) Is determined (D3), and if not in service (OUS), lamp control of the common unit is performed (D10), and the status management table of the cascade 0 system is indicated as “own system service status → OUS”. Then, the own system service state information is updated to non-service (OUS) (D11), and the processing ends.
[0058]
If the result of the determination in step (D3) indicates that the own system service status information is in service (INS), the cascade 1 system switching control unit requests the upper operation system OpS to disconnect the link with the cascade 0 system (D4). Upon receiving the link disconnection response from the operation system OpS, the link to the cascade 0 system is disconnected (D5). Then, as shown in the status management table of the cascade 1 system as “own system operation status → ACT, other system operation status → SBY”, the self system operation status information is in operation (ACT), and the other system operation status information is not operated. It is updated to medium (SBY), and ramp control is performed (D6). Next, switching of the subscriber line IF section under its own subrack and lamp control are performed (D7), and a link request for the cascade 1 system is made from the cascade 0 system switching control unit to the host operation system OpS (D8). A link response to this is received, a link to 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 occurs. The same reference numerals as in FIG. ₀ , 70 ₁ , 74 ₀ , 74 ₁ , 77 ₀ , 77 ₁ Is the switch unit, 71 ₀ , 71 ₁ , 75 ₀ , 75 ₁ , 78 ₀ , 78 ₁ Denotes a monitoring control unit, 72 ₀ , 72 ₁ Is the intra-office IF section, 73 ₀ , 73 ₁ , 76 ₀ , 76 ₁ , 79 ₀ , 79 ₁ Indicates an OpS-IF unit.
[0060]
In the case where the inside of the bold line in FIG. 21 is operating (ACT), that is, 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 a switching factor occurs in the basic subrack 50 in a state in which only the basic subrack 50 is in operation, the operation indicated by the next parenthesized number in the order and route of parenthesized numbers in FIGS. 21, 22, and 23. Is performed.
[0061]
(1). Common part 53 of system 0 of basic subrack 50 ₀ When a switching factor such as a failure, a common unit package removal, or a reset occurs, the switching factor is set to the switching control unit 61 between the 0-system and the 1-system. ₀ , 61 ₁ And the switching control unit 61 ₀ , 61 ₁ Detects this. In addition, the common unit 53 of the 0 system ₀ Is removed, the switching control unit 61 of the first system ₁ Will detect the switching factor.
(2). The service status of the first system of the basic subrack 50 is set, for example, in a status management table having the setting contents as shown in FIG. 17 (this status management table can be provided in the monitoring control system of the common unit. Is omitted) to check whether switching is possible. When not in service (OUS), only lamp control and updating of the state management table are performed.
[0062]
(3). Switching control section 61 of basic subrack 50 between system 0 and system 1 ₀ , 61 ₁ Updates the state management table and performs lamp control in response to occurrence of various factors including switching factors. When the contents of the status management table corresponding to the system 0 of the basic subrack 50 are updated, the contents of the status management table of the system 1 of the basic subrack 50 corresponding to other systems are updated. In this case, when the operation of the system 0 of the basic subrack 50 is impossible or when the package is removed, the switching control unit 61 of the system 1 of the basic subrack 50 is used. ₁ By setting the contents of the status management table corresponding to the other system, the switching process can be executed normally even when the operation of the other system is not possible.
(4). 1st system switching control unit 61 of basic subrack 50 ₁ Sends a request to the higher-level operation system OpS to disconnect the link with the system 0 of the basic subrack 50, using the OpS-IF unit 73. ₀ To send over. In addition, the common unit 53 of the 0 system ₀ This process is omitted when the package is removed.
[0063]
(5). When a link disconnection response is received from the upper operation system OpS, the link with the 0 system is disconnected.
(6). Then, the switch unit 70 in the order of the 1 system and the 0 system ₁ , 70 ₀ And lamp control is performed. The above shows the processing in FIG.
[0064]
(7). Switching control unit 61 of system 0 of basic subrack 50 ₀ Updates the status management table when the operation status of the system 1 is operating (ACT) and the operation status of the system 0 is not operating (SBY), and transmits an instruction to switch the common unit to the cascade connection destination. . That is, the common portion 53 of the basic subrack 50 ₁ Is indicated as being in operation (ACT) as indicated by a bold line, and a cascade connection destination is instructed.
(8). For example, the selector 13 or the like shown in FIG. 3 is controlled for the subscriber line IF unit (not shown) of the basic subrack 50 to switch the connection between the 0-system and the 1-system common unit, and Perform control.
[0065]
(9). Only when the local station IF operation status information of the status control table of the first system of the basic subrack 50 is not operating (SBY), the switching of the intra-office IF section is executed in accordance with the APS (Automatic Protection Switch) regulation, and the switching process is performed. At the time of execution, the intra-station IF section operation state information is updated and lamp control is performed (only for the basic subrack). That is, by switching the intra-office IF unit only when necessary, it is possible to suppress the influence of a failure inside the device on the outside.
[0066]
(10). Regardless of the progress of the switching process of the cascade subrack, the 0-system switching control unit 61 of the basic subrack 50 ₀ Sends a link request to the upper-level operation system OpS with the system 1 of the basic subrack 50.
(11). In response to a link response from the higher-level operation system OpS, a link with the first subrack 50 is performed, and the switching control unit 61 ₀ Can be quickly shifted to a state in which switching control is possible.
[0067]
In the cascade subrack 51, 52, the following processes (7), (9) to (15) are performed as shown in FIGS. That is,
(7). Switching control unit 62 of system 0 and system 1 of cascade subrack 51 and 52 ₀ , 62 ₁ , 63 ₀ , 63 ₁ Is the common part 53 of the first sub-rack 50 ₁ Receiving the common unit switching instruction from the PC.
(9). With reference to the service status of the first system of the cascade subrack 51, 52, it is checked whether the switching operation is possible. 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). One-system switching control unit 62 of cascade subrack 51, 52 ₁ , 63 ₁ Sends a request to the higher-level operation system OpS to break the link with the 0-system of the cascade subrack 51, 52. ₀ , 79 ₀ Out via.
(11). When a link disconnection response to the link disconnection request is received, it is determined that the system is 0 and the link is disconnected.
[0069]
(12). One-system switching control unit 62 of cascade subrack 51, 52 ₁ , 63 ₁ Updates the status management table so that the operation status information of the own system is ACT and the operation status information of the other system is SBY, and performs lamp control.
(13). The subscriber line IF under the own subrack is switched in the same manner as in the above-mentioned process (8) to perform lamp control.
[0070]
(14). 0-system switching control unit 62 of the cascade subrack 51, 52 ₀ , 63 ₀ As shown in FIG. 23, the OpS-IF unit 76 ₁ , 79 ₁ A request for linking with one of the cascade subrack 51 and 52 is transmitted via the.
(15). Upon receiving a link response to the link request, the link is linked to one of the cascade subrack 51, 52.
[0071]
As described above, the switching control units on the non-operational (SBY) side are in a state of communicating with each other as shown in FIG. Switching control unit 61 on the operation (SBY) side ₁ With the control processing of, the cascade subrack 51, 52 also switches from the system 0 to the system 1 to the system 1 of the basic subrack 50 and the system 1 of the cascade subrack 51, 52. The system is cascade-connected to be in operation (ACT). In this state, the system 0 of the basic subrack 50 and the system 0 of the cascade subrack are switched to be in operation (ACT) due to the occurrence of the switching factor of the system 1 of the basic subrack 50.
[0072]
FIGS. 24 to 27 show flowcharts when the cascade subrack common part 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 a state where the system 0 is in operation (ACT), a failure occurs during the operation of the cascade subrack (ACT), so that the system 0 and system 1 of the basic subrack are switched from the system 1 of the cascade subrack. Is received (E1). Hereinafter, “subrack” is omitted as long as confusion does not occur.
[0073]
With reference to the status management table of the basic 1 system, it is determined whether the own system is in service (INS) or not (E2). If not, the process is terminated (completion). If the service is in service (INS), it is determined whether the own system cascade number is the same as the other system cascade number with reference to the status management table of the basic system 1 (E3). If not, the process ends. If they are the same, it is determined whether or not the own system failure state is set to normal in the state management table of the basic system 1 (E4).
[0074]
In this determination, if abnormal, the process is terminated. If normal, the switching control unit 61 of the basic 1 system. ₁ (See FIG. 21) sends a request to disconnect the link to the basic 0 system to the host operation system OpS (E5). When a link disconnection response is received from the higher-level operation system OpS, the link with the basic 0 system is disconnected (E6).
[0075]
And a switch unit 70 for the system 0 and the system 1 ₀ , 70 ₁ Is switched and lamp control is performed (E7). Next, as shown in the status management table of the basic 1 system as “own system operation status → ACT, other system operation status → SBY”, own system operation status information is operating (ACT), and other system operation status information is non-operation. The status is updated to medium (SBY), a common unit switching instruction is transmitted to the cascade connection destination of the 0 system and the 1 system, and lamp control is performed (E8). Then, the processing of the cascade subrack is started (E14), the switching of the subscriber line IF under the subrack subrack is performed, and the lamp control is performed (E9). It is determined whether or not the operation status information of the intra-office IF unit is not operating (SBY) (E10).
[0076]
In the case of non-operation (SBY), switching of the intra-office IF section and updating of the status management table are performed, as shown as 1-station internal IF section operation state → ACT, 0-system intra-station IF section operation state → SBY. In the status management table, the operation status information of the IF unit in the 1-system station is updated to “operating” (ACT), and the operation status information of the IF unit in the 0-system station is updated to “non-operating” (SBY) (E11). Move to step (E12). If it is determined in step (E10) that the device is in operation (ACT), the process proceeds to step (E12). In this step (E12), the switching control unit 61 of the basic 0 system ₀ Sends a request for linking with the basic system 1 to the higher-level operation system OpS. When a link response to the link request is received, a link to the basic system 1 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 of ₀ When a failure occurs in both the switching control units 62 ₀ , 62 ₁ (F1).
Then, it is determined with reference to the status management table of the cascade 1 system whether or not the own system service status information is in service (INS) (F2).
[0078]
If not in service (OUS), ramp control indicating a common part of the occurrence of a failure is performed (F3), and if in service (INS), it is determined whether the cascade 0 system is operable (F4). If the operation is not possible, the other-system service status information is set to non-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 state information is abnormally updated (F6). If operable, the cascade 0 system status management table indicates “own service status → OUS, own board failure status → abnormal”, and the own system service state information is not in service (OUS). The failure status information is updated abnormally (F5).
[0079]
Then, a switching notification is sent to the basic subrack (F7), a basic switching process waiting timer is started, and it is determined whether or not the timer has timed out (F8). Then, it is determined whether or not a common unit switching instruction has been received from the basic system 1 (F9), and if not, the process proceeds to step (F8). If it has been received, it is determined whether or not its 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 ends. If the service is in service (INS), the switching control unit of the cascade 1 system sends a request to disconnect the link to the cascade 0 system to the host operation system OpS (F11).
[0080]
When a link disconnection response to this link disconnection request is received, the link with the cascade 0 system is disconnected (F12), and the status management table of the cascade 1 system is shown as “own system operation status → ACT, other system operation status → SBY”. Then, the self-system operation state information is updated during operation (ACT) and the other system operation state information is updated during non-operation (SBY), and lamp control is performed (F13). Then, switching of the subscriber line IF section under its own subrack and lamp control are performed (F14), and a link request for the cascade 1 system is made from the switching control section of the cascade 0 system to the host operation system OpS (F15). When a link response to this link request is received, a link to the basic system 1 is formed (F16).
[0081]
28, 29, and 30 are explanatory diagrams when a cascade subrack switching factor occurs, and the same reference numerals as those in FIG. 21 indicate the same parts. In the state where the inside of the bold line in FIG. 28 is operating (ACT), that is, the common unit 53 of the 0 system 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 ₃ In the switching control operable state, when a switching factor occurs in the cascade subrack 51, the order and route of parenthesized numbers in FIGS. 28, 29, and 30 are indicated by the following parenthesized numbers. The basic subrack side operation and the cascade subrack side operation are performed.
[0082]
Basic subrack operation
(4). The basic 0-system and 1-system switch control units 62 of the cascade 1-system due to the occurrence of a switching factor in the cascade 0 system. ₁ Then, as shown in FIG. 28, a switching factor occurrence notification is received.
(5). It is determined with reference to the state management table whether switching is possible. If the service status of the basic system 1 is out of service (OUS), the switching process is not executed. That is, by giving the highest priority to the state of the basic subrack, it is possible to prevent system inconsistency. The same processing is performed when the number of common parts of the two systems connected in cascade is different, or when the other system fault state information is abnormal.
[0083]
(6). Basic 1 system switching control unit 61 ₁ Is the OpS-IF unit 73 of the basic 0 system ₀ A request to disconnect the link with the basic system 0 is transmitted to the higher-level operation system OpS via the.
(7). The link disconnection response from the higher-level operation system OpS is sent to the basic 0-system OpS-IF unit 73. ₀ , The switching control unit 61 of the basic system 1 ₁ Is received, the link to the basic 0 system is disconnected.
[0084]
(8). Next, as shown in FIG. ₁ Is the switch unit 70 of both systems ₀ , 70 ₁ Are switched in the order of the system 1 and the system 0 to perform the lamp control.
(9). Basic 0 system switching control unit 61 ₀ Is set in 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 in non-operation (SBY). Transmits a common unit switching instruction. In addition, lamp control is performed.
[0085]
(10). The subscriber line IF section under its own subrack is switched to perform lamp control.
(11). Only when the operation status information in the local station IF section in the status management table of the basic 1 system is not operating (SBY), the switching of the local IF section is executed in accordance with the APS rules. Update department operation status information.
(12). Basic 0 system switching control unit 61 ₀ Transmits a link request with the basic system 1 to the upper-level operation system OpS.
(13). The link response to the link request is received, and the link to the basic 1 system is made.
[0086]
Cascade subrack side operation
(1). As shown in FIG. 28, the common unit 54 of the cascade 0 system ₀ When the switching factor occurs in the cascade, the switching control unit 54 of both cascade systems ₀ , 54 ₁ Detects this switching factor occurrence notification.
(2). When the service state of the cascade 1 system is referred to, and the service is out of service (OUS) due to a failure, not mounted, or the like, the state management table is updated and the lamp control is performed.
If the service is in service (INS), the status management table is updated according to the switching factor, and lamp control is performed.
[0087]
(3). The cascade 1 system notifies the basic subrack 50, activates a basic subrack switching processing waiting timer, determines that the basic subrack has not been able to perform the switching process when it times out, and switches to the basic subrack system. No switching process is performed to match. That is, this corresponds to the timeout in step (F8) of FIG. 26, and the subsequent processing is terminated. Thereafter, the above-described 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 unit 54 of both systems of the cascade is used. ₀ , 54 ₁ Receives the common unit switching instruction from the first basic system.
(11). It is checked whether the service status information of the other system in the cascade 0 system and the cascade 1 system in which the switching factor has occurred is out of service (OUS), and whether the other board failure status information is abnormally set. If not set, the status is set to non-service (OUS) and abnormal, respectively, and lamp control is performed.
[0089]
(12). Switching controller 62 of cascade 1 system ₁ , 63 ₁ Is the OpS-IF unit 76 for the upper operation system OpS. ₀ , 79 ₀ To send a link disconnection request.
(13). From the upper operation system OpS, the OpS-IF unit 76 ₀ , 79 ₀ When a link disconnection response is received via the link, the link to the cascade 0 system is disconnected.
[0090]
(14). The cascade 1 system updates the state management table so that the operation state information of its own system is in operation (ACT) and the operation state information of the other system is in non-operation (SBY), and performs lamp control.
(15). As shown in FIG. 30, the subscriber line IF section 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 host operation system OpS.
(17). Upon receiving a link response from the higher-level operation system OpS, it links to the cascade 1 system.
[0091]
FIG. 31, FIG. 32, and FIG. 33 are operation flowcharts at the time of forced switching of the common unit, and FIG. 34, FIG. 35, and FIG. The common unit forced switching is executed by a forced switching command for switching from the system 0 to the system 1 or vice versa for the common unit package exchange from the host operation system or the like, or vice versa. 31 and FIG. 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 denote 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 the processing steps (H1) to (H15) will be described with respect to the operation order of (1) to (17).
[0092]
Basic subrack side operation (see FIGS. 31, 32, 34 to 36)
(1). Basic 0 system OpS-IF unit 73 ₀ Receives the forced switching command from the host operation system OpS (G1), the switching control unit 61 of the basic 1 system ₁ The 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 status management table of the basic system 1 and checks whether or not switching is possible. That is, it is determined whether or not the own system service status information is in service (INS) (G4). In the case of non-service (OUS), a compulsory switching error to the higher-level operation system OpS is sent to the OpS-IF unit 73. ₀ (G6).
[0093]
(4). When the own system service status information is in service (INS), the switching control unit 61 of the basic first system ₁ Sends a request to the higher-level operation system OpS to disconnect the link with the basic 0 system, to the OpS-IF unit 73. ₀ (G5).
(5). Switching control unit 61 ₁ Transmits a link disconnection response from the host operation system OpS to the OpS-IF unit 73. ₀ Is received, the link to the basic 0 system is disconnected (G7).
(6). Switch 70 for both systems ₀ , 70 ₁ Are switched in the order of the 1-system and the 0-system to perform the lamp control (G8).
[0094]
(7). Basic 0 system switching control unit 61 ₀ Updates the operating status information of the other system in the status management table to active (ACT) and updates the operating status information of the own system to non-operating (SBY). A switching instruction is transmitted to perform lamp control (G9). The cascade subrack starts processing according to the common unit switching instruction (G16).
(8). Switching of the subscriber line IF subordinate to the own subrack and lamp control are performed (G10).
[0095]
(9). Basic 0 system switching control unit 61 ₀ Is the intra-office IF unit 72 ₀ , 72 ₁ Is switched.
(10). Basic 0 system switching control unit 61 ₀ Sends a link request to the upper system to the upper operation system OpS (G11).
(11). The link response from the host operation system OpS is received, and the link is linked with the basic system 1 (G12).
[0096]
(16). Basic 0 system switching control unit 61 ₀ Receives the common part compulsory completion signal from the cascade connection destination (G13).
(17). Basic 0 system switching control unit 61 ₀ Determines whether the common unit forced switch completion signal is from the cascade 1 system registered in the state management table (G14). If the determination is confirmed, the upper-level operation system OpS completes the forced switch. Send a 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 has been received from the primary system 1 (H1).
(9). When it is received, it refers to the status management table of the cascade 1 system, and determines whether or not its own service status information is in service (INS) (H2). In the case of non-service (OUS), the lamp control (H4) of the common unit and the own system service status information of the status management table of the cascade 0 system are updated to non-service (OUS) (H5).
[0098]
(10). If the service status information of the own system is in service (INS), the switching control unit 62 of the cascade 1 system ₁ , 63 ₁ Sends a link disconnection request to the cascade 0 system to the host operation system OpS (H3).
(11). When a link disconnection response is received from the upper operation system OpS, the link to the cascade 0 system is disconnected (H6).
(12). The cascade system 1 updates the own system operation state information in the state management table to the operation state (ACT) and the other system operation state information to the non-operation state (SBY) (H7), and performs lamp control.
[0099]
(13). As shown in FIG. 36, switching of the subscriber line IF subordinate to the 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 upper operation system OpS. ₁ , 79 ₁ (H9).
[0100]
(15). The link response from the host operation system OpS is received, and the link is linked with the cascade 1 system (H10).
(16). Basic 0 system switching control unit 61 ₀ (Step H11).
As described above, by inputting the compulsory 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. Can be operated in a cascade connection.
[0101]
FIG. 37 is a flowchart showing the operation of the system 0 when both systems are started simultaneously, FIGS. 38 and 39 are flow charts showing the operation of the system 1 when both systems are started simultaneously, and FIGS. 40 and FIG. 41, the subscript 0 indicates the 0 system, 1 indicates the 1 system, and ₀ , 81 ₁ Is the common part, 82 ₀ , 82 ₁ Is a monitoring control unit, 83 ₀ , 83 ₁ Is the OpS-IF section, 84 ₀ , 84 ₁ 85, parts in the apparatus such as a switch unit and an in-station IF unit ₀ , 85 ₁ Is the memory in the device, 86 ₀ , 86 ₁ Represents a backup memory, and 87 represents a subscriber line IF unit.
[0102]
The operation sequence (1) to (16) in FIGS. 40 and 41 and the steps (J1) to (J15), (K1) to (K15), and (L1) to (L5) in FIGS. Will be described in association with the above.
[0103]
(1). Power on or insert the package (J1), (K1).
(2). Monitoring control unit 82 ₀ , 82 ₁ Are started (J2) and (K2), the self-startup state information in the state management table is set to "starting" (J3) and (K3), and lamp control is performed.
(3). Common part 81 ₀ , 81 ₁ (J4) and (K4).
[0104]
(4). The start-up method is determined with reference to the state management table (J4) and (K5).
(5). The system 1 sets a timer (K6), and determines whether or not the system 0 has started based on the presence or absence of a timeout (K7). In the case of a timeout, the common unit 81 of the first system ₁ Is activated (ACT) (K14). This start-up processing can be the same as the processing of steps (J6) to (J14) in FIG. If it is not time-out, it is determined whether or not the start-up completion notification from the system 0 has been received (K8).
[0105]
(6). 0 system is its own backup memory 86 ₀ Data in the device memory 85 ₀ (J5).
(7). The data is uploaded from the activated subscriber line IF unit 87 under the sub-rack, and the ₀ Is updated, and the data is downloaded to the unestablished subscriber line IF unit 87. It is determined whether or not the processing for the number of the subscriber line IF units 87 under the own subrack has not been completed (J7). If not completed, whether the subscriber line IF units 87 under the own subrack have been started up. It is determined whether or not it has been started (J8). ₀ The data of the subscriber line IF unit 87 is uploaded to the server (J9). ₀ The data is downloaded to the subscriber line IF unit 87 (J10), and the process proceeds to step (J7).
[0106]
(8). If the result of determination in step (J7) is that processing has ended, own-system (0-system) operating state information in the own-system state management table is updated to operating (ACT), and lamp control is performed (J11).
(9). The self-system start-up state information in the state management table of the 0-system is set to “started”, and the self-system service state information is updated to “in service” (INS) (J12).
[0107]
(10). Monitoring and control unit 82 of system 0 ₀ Sends a link request to the host operation system OpS (J13).
(11). A link response is received from the higher-level operation system OpS and linked (J14), and the start-up completion and operation status (ACT) are notified to the common part of the other system (J15).
[0108]
(12). The system 1 receives the start-up completion notification of the system 0, determines whether or not the system 0 is in normal operation with reference to the state management table (K9). ₁ Is activated (ACT) (K15). The start-up processing in this case can be the same as the processing of steps (J6) to (J14) in FIG. In the case of normal operation, the 0-system backup memory 86 ₀ To system 1 backup memory 86 ₁ The data is copied to (K10).
(13). 1 system is its own backup memory 86 ₁ Data in the device 85 ₁ (K11).
[0109]
(14). The first system sets the operation status information of its own system to non-operation (SBY), sets it in the status management table, and performs lamp control (K12).
(15). The first system sets the own system start-up state information in the state management table to “started” and sets its own system service state information to “in service (INS)” (K13).
[0110]
In the case of starting the cascade subrack, the operation status information of the cascade subrack is checked with the operation status information of the basic subrack by referring to the status management table. Performs the switching process so that they match. Therefore, the cascade subrack can be set up so that the same system is used for the system 0 or system 1 of the basic subrack.
[0111]
The present invention is not limited to each of the above-described embodiments, and various additions and changes can be made. For example, in a subrack unit, a larger number of subrackes are cascade-connected to a basic subrack. It is also possible. Means for performing 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 provides a common unit in which a monitoring control system including the monitoring control unit 5 and the switching control unit and a main signal system including the intra-office 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 having a redundant configuration of n: 1 and the station-side 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 monitoring control system on the non-operating (SBY) side controls the system switching. The cost can be reduced by manufacturing packages having the same configuration as the two types of the common unit and the subscriber line IF unit.
[0113]
Further, for the redundantly configured monitoring control system, system switching is performed when a switching factor occurs by using the switching control unit of the non-operating common unit, thereby eliminating the need for control by the monitoring control unit of the operating common unit. Therefore, there is an advantage that system switching can be performed at high speed.
[0114]
In addition, a subrack including a common part of the system 0 and the system 1 is used, one is used as the basic subrack 50, and the other subrack 51, 52 is cascaded, so that the subrack can be easily added in subrack units. There are advantages that are possible. Further, each subrack has a redundant configuration including a common part of the system 0 and the system 1, and when a switching factor occurs, the switching control unit of the monitoring control system of the basic subrack switches the switching control unit of the monitoring control system of the cascade subrack. , 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 a start-up process.
FIG. 7 is an explanatory diagram of a common part confounding connection.
FIG. 8 is an explanatory diagram of a system switching configuration.
FIG. 9 is an explanatory diagram of a system switching process based on a switching factor.
FIG. 10 is an explanatory diagram of a cascade connection configuration according to the embodiment of the present invention.
FIG. 11 is an explanatory diagram of registered contents.
FIG. 12 is an explanatory diagram of a definition of registered contents.
FIG. 13 is an explanatory diagram of inter-subrack communication.
FIG. 14 is an explanatory diagram of state information during operation.
FIG. 15 is an explanatory diagram when a failure occurs.
FIG. 16 is an explanatory diagram when the operation state changes.
FIG. 17 is an explanatory diagram of a state management table.
FIG. 18 is a flowchart when a basic subrack common part fails.
FIG. 19 is a flowchart when a basic subrack common unit fails.
FIG. 20 is a flowchart of a cascade subrack process.
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 forcible switching of the common unit.
FIG. 32 is an operation flowchart at the time of forcible switching of the common unit.
FIG. 33 is an operation flowchart at the time of forced switching of the common unit.
FIG. 34 is an explanatory diagram of the operation at the time of forcibly switching the common unit.
FIG. 35 is an explanatory diagram of the operation at the time of forcibly switching the common unit.
FIG. 36 is an explanatory diagram of the operation at the time of forcibly switching the common unit.
FIG. 37 is a flowchart of the operation on the system 0 side when both systems are started up simultaneously.
FIG. 38 is an operation flowchart of the first system when both systems are simultaneously started.
FIG. 39 is an operation flowchart of the first system when both systems are simultaneously started.
FIG. 40 is an explanatory diagram of the operation at the time of simultaneous startup of both systems.
FIG. 41 is an explanatory diagram of the operation at the time of simultaneous startup of both systems.
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
4 Main signal section
5 Monitoring and control unit
6 Clock section
7 Switch section
8 Internal IF section
9 Extended IF section

Claims (7)

Communication including a subscriber line IF unit having a redundant configuration accommodating a plurality of subscriber lines, a main signal unit including an intra-office IF unit and a switch unit, a monitoring control unit, and a switching control unit for controlling system switching. In the device,
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 intra-office IF unit and the switch unit are packaged in one package;
The common part has a redundant configuration of the 0 system and the 1 system,
The supervisory control unit of the supervisory control system in the common unit including the active main signal system of either the 0 system or the 1 system performs the supervisory control of the active main signal system, and performs the non-operating main signal system. A redundant configuration communication device, wherein a switching control unit of a monitoring control system in a common unit including a main signal system has a configuration for performing system switching control by generating a switching factor of the operating main signal system. The switching control unit has a configuration in which an in-station IF unit and a switch unit, which constitute a main signal system of a common unit of the 0 system and the 1 system, are entangled and connected via a selector. The redundantly configured communication device according to claim 1, further comprising a configuration for performing switching or confounding connection switching by the selector control. Communication including a subscriber line IF unit having a redundant configuration accommodating a plurality of subscriber lines, a main signal unit including an intra-office IF unit and a switch unit, a monitoring control unit, and a switching control unit for controlling system switching. In the device,
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 intra-office IF unit, the switch unit, and the cascade IF unit are packaged in one,
One of the subracks in which the common part has a redundant configuration of the system 0 and the system 1 is a basic subrack serving as a master, and the other is a cascade subrack serving as a slave. On the other hand, the 0-system and 1-system of the cascade subrack are connected to each other via the cascade IF unit, and a switching factor in a common part of the operating system of either the 0-system or the 1-system. Due to the occurrence, the switching control unit of the non-operating common unit of the basic subrack notifies the switching control unit of the non-operating common unit of the cascading subrack, and the switching of the basic subrack and the cascade subrack is performed. A redundant configuration communication device having a configuration for performing system switching. In a common part of the system 0 and the system 1 constituting the subrack, own system operation status information indicating whether the own system is operating or not operating and own system indicating whether the own system is operating or not operating A state that stores service state information, state information including own system 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 the basic subrack. 4. The redundant communication device according to claim 3, further comprising a management table. The common part of the system 0 and the system 1 has a backup memory for storing backup data for taking over the operation state, and has a configuration in which the system identification data at the time of startup is stored in the backup memory. The redundantly configured communication device according to claim 1 or 4, wherein: A redundant configuration communication in which a monitoring and control system including a monitoring control unit and a switching control unit, and a main signal system including an intra-office IF unit and a switching unit are packaged into a single unit and a common unit is configured as a redundant configuration of a 0 system and a 1 system. When a switching factor occurs in one of the operating main signal systems of the 0 system and 1 system, the switching control of the non-operating monitoring control system of the other of the 0 system and 1 system is performed. A system switching method including a step of controlling system switching by a unit. 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 intra-office IF unit, a switch unit, and a cascade IF unit are packaged into one package is redundantly configured as a 0 system and a 1 system. One of the sub-racks is a basic sub-rack, the other is a cascade sub-rack, and the system 0 and the system 1 of the cascade sub-rack are connected to the cascade IF with respect to the system 0 and the system 1 of the basic sub-rack. When a switching factor occurs in one of the operating main signal systems of either the 0-system or the 1-system of the redundant communication device connected via the unit, any of the 0-system and 1-system of the basic subrack is generated. Or the switching control unit of the other non-operating monitoring control system is notified of the switching factor, and the switching control unit notifies the switching control unit of the non-operating monitoring control system of the cascade subrack of the system switching. , The basic subrack and the cascade System switching method characterized by comprising the step of switching the subrack so that the same system.

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