JP5427137B2 - Optical signal distribution apparatus and system - Google Patents

Description

  The present invention relates to an optical signal distribution device and system, and more particularly to an optical signal distribution device and system that can easily adapt a system configuration to changes in the number of optical video signal distributions as needed.

With the advancement of optical communication technology, optical CATV distribution services using optical fiber that has not been affected by interference noise that has been emitted from various factors such as weather, buildings, etc., have been spreading. ing.
In an optical CATV distribution service based on an HFC (Hybrid Fiber Coax) system, a television broadcast signal is converted into an optical signal by a video distribution device (head end) in an operator building, and an optical node device installed outdoors using an optical fiber. Is transmitted and converted to an electrical signal. The converted electrical signal is transmitted to the vicinity of the user's home via a coaxial cable, and is split into a plurality of coaxials by a distributor and distributed to the user's home.
In an optical CATV distribution service based on the FTTH (Fiber To The Home) system, which is an advanced form of the HFC system, a television broadcast signal is converted into an optical signal by a video distribution device (head end), and is installed in the same or another building of the operator. The signal is sent to the optical video signal distribution device, amplified using the optical amplifier and the optical branch as it is, branched into a plurality of optical outputs, and distributed to the optical video signal receiver in the user's home via an optical fiber.
In the HFC (Hybrid Fiber Coax) system, a television broadcast signal converted into an electrical signal is transmitted to a new user by connecting an amplifier as necessary and extending the coaxial cable to the vicinity of the user's house. Then, it is branched by a distributor and distributed to the user's house. On the other hand, in the FTTH system, since the amplification and branching of the television broadcast signal are performed in the business building, an optical video signal distribution device that can increase the number of service users planned in advance is installed. Thus, in the HFC (Hybrid Fiber Coax) system. Whereas an electrical signal amplifier and a branch can be added as appropriate, the FTTH method requires that an optical video signal distribution device capable of accommodating the planned number of users accommodated be installed at the time of installation.
An optical amplifier using an optical fiber to which rare earth such as erbium is added is used to amplify the optical signal in the optical video signal distribution device, and the optical output and the number of branches that can cope with the increase in the number of users. An amplifier and optical branching are used. However, because the optical output and amplification amount of optical amplifiers are technically limited, if the number of users to be accommodated is large and the number of branches must be increased, optical amplifiers are cascaded to the branch output of the optical amplifier. Increase the number. In response to the increase in the number of users, in the optical video signal distribution apparatus, units are added in units of optical amplifiers and optical branches. Also, in an optical video signal distribution device with a large number of branches, the television broadcast signal from the head end is duplicated, and when the television broadcast signal fails with an optical switch, it is switched to a redundant television broadcast signal. Means for reducing damage to the user are used. In order to cope with the expansion of the user's area, a television broadcast signal is also transmitted to the optical video signal distribution device in another building by relaying the optical video signal distribution device in the business building.
FIG. 8 shows an example of the FTTH system described above. A television broadcast signal transmitted from the optical video distribution apparatus is relayed to building B and building C via building A. Depending on the number of users in the service areas handled by the buildings A, B, and C, the appropriate number of cascaded optical amplifier stages and the number of optical switches for redundant switching differ, and the configuration changes. In the building A, the duplexed television broadcast signal transmitted from the video signal distribution apparatus is amplified and branched, and one of the branch outputs is sent to the building B. The other branch output is input to two optical switches, distributed by a two-stage optical amplifier and an optical branch, and sent to a user's home. In the building B, the duplexed optical signal television broadcast signal via the building A is sent to the user's house in the same manner as the building A. The difference is that there are three optical switches, and the number of distributions is large accordingly. Bill C distributes the television broadcast signal of the duplexed optical signal that passes through Building B with a single-stage optical amplifier and optical branch, and sends the television broadcast signal to the user's home, and the number of distribution is small. It has become.
FIG. 9 shows an example of the cabinet of the optical video signal distribution device of FIG. The plug-in unit A for mounting the optical amplifier and the optical branch and the plug-in unit B for mounting the optical switch and the optical branch are mounted according to the configuration. The optical fiber cable connected to the optical input / output connector of the plug-in unit is connected to the connector on the front side of the cabinet. In such a system, the operation state, management information, and control of each cabinet are collected in a monitoring control panel, and are monitored and controlled by communicating with a terminal of a remote monitoring control system. Non-patent documents 1, 2, and 3 are documents related to the optical video signal distribution device described above.

Fujikura Technical Review No. 107 “High-density packaging optical fiber amplifier for video distribution” Mitsubishi Cable Industrial Time Report No. 101 “Development of SNMP-compatible plug-in unit optical fiber amplifier for FTTH” SEI Technical Review No.166 “Development of Video Signal Optical Amplifier”

Not only the CATV service that is the subject of the present application, it is difficult to predict the spread speed of broadcasting / information communication services and the maximum number of users because various factors overlap. Content can be explosive and popular, and it can be replaced by the emergence of new services without the creation of such. Therefore, it is desirable for an operator to start a service with a minimum system configuration and expand the system as the service expands. For example, if the service is started with the building C system configuration of FIG. 8 and the existing configuration can be stacked and expanded without discarding the system configuration of building A and building B as the number of users increases, the service can be provided at an appropriate investment cost. Can be expanded.
When the cabinet for building C is expanded to that for building A, an additional cabinet is added (device numbers 2, 3, and 4), plug-in unit A is mounted on this, and an optical fiber is input to the optical amplifier. It is necessary to change the system configuration by cascading optical signals sent to the user's home with a cable. In order to further expand the system configuration from building A to building B, plug-in unit B is newly mounted in an expansion cabinet as a single unit, and plug-in unit A composed of the first-stage optical amplifier and optical branching is added to this. Can be expanded to the system configuration of Building B. In order to easily perform such a system configuration change, it is preferable that both the plug-in units A and B can be arbitrarily mounted in the mounting slot of the plug-in unit of the cabinet. However, the problem here is that system maintenance becomes complicated. For example, since the connection of the optical fiber cable is changed by changing the system configuration, the optical input connector of the plug-in unit A is connected to which optical output connector of the plug-in unit A or B installed in which slot. However, since the connection between the connectors is an optical fiber cable without electrical connection, the connection information between the connectors of the plug-in unit is connected with the optical fiber cable between the connectors in the monitoring control panel. It is not possible to automatically detect automatically by just doing.

Conventionally, the type and mounting position of the plug-in units to be installed are fixed, and the optical fiber cable wiring between the plug-in units is also fixed accordingly. Or, registered in the supervisory control system, the optical fiber cable wiring can be automatically detected by the supervisory control panel, and the connection destination information can be displayed on the plug-in unit in an updatable manner to the maintenance personnel There was no. Also, cable connection information was recorded in a plug-in unit for connecting an optical fiber cable, and it was not updated. Therefore, as described above, if the plug-in unit is mounted arbitrarily and the optical fiber cable is wired or updated during operation, the plug-in unit mounting and the optical fiber cable connection work are separate. It is necessary to input and update connection information such as the connection destination, connection source mounting position, and type of the optical fiber cable plug-in unit from a terminal such as a PC connected to the monitoring control panel or monitoring control system. Become. In this specification, for example, “connection destination” indicates upstream of signal distribution, and “connection source” indicates downstream of signal distribution.
However, in this case, since the work target is the plug-in units A and B, and the connection information input work is physically separated by the monitoring control panel and the remote monitoring control system, there is a mistake in information input. In some cases, an erroneous connection may occur, resulting in a mismatch between the actual connection and the input information. When the optical output of the plug-in unit A is interrupted due to a failure, the downstream plug-in unit A or B that receives the optical output has no optical input, so that the fault is spread, and the optical input cutoff fault is detected The The monitoring and control panel collects these fault information. However, if there is an incorrect connection as described above, information on which plug-in unit is upstream or downstream cannot be grasped correctly. The faulty plug-in unit may not be identified. In addition, in the monitoring control panel or remote monitoring control system, when a failure occurs, the warning display LED on the front panel of the failed plug-in unit is lit to indicate to the maintainer the plug-in unit to be replaced. As will be clearly shown, both the alarm display LED of the fault plug-in unit and the alarm display LED of the plug-in unit to which the fault has spread are both turned on at each fault alarm. In this case, in order to obtain connection information for the target plug-in unit, the maintenance person collects connection information from the monitoring control panel or checks the connection status while tracing the connected optical fiber cable in front of the cabinet. After that, the faulty plug-in unit must identify which one. In addition, since the remote monitoring and control system cannot see the actual connection state of the optical fiber cable, it is difficult to identify the faulty plug-in unit.
In the past, optical fiber cable connection work was based on design drawings or manufacturing drawings, but optical fiber cable connections were made. Therefore, there is a possibility that the connection of the optical fiber cable in operation may be mistakenly disconnected or a connection leak may occur. Also, whether or not the actual fiber optic cable connection is correct is conventionally tested at the time of manufacture and before operation, but it is also necessary to check when the connection of the fiber optic cable is updated. Similarly, if the test is confirmed based on the design drawing or the manufacturing drawing, there is a possibility that the test is mistaken and a service failure during operation is caused.
In view of the above points, the present invention provides information on the connection of optical fiber cables between plug-in units on the panel (front panel, etc.) of the plug-in unit to be connected at the time of optical fiber cable connection work. Connection information that matches the displayed content is automatically notified to the monitoring control panel and the remote monitoring control system, which facilitates work and causes incorrect connections. The purpose is to make it difficult.

In the present application, for the purpose of solving the above-mentioned problems, when connecting an optical fiber cable between plug-in units, an operator uses a means such as a rotary switch on the front panel of the plug-in unit to use the optical fiber cable. The connection destination is displayed, and the displayed information is electrically registered. That is, the display information is transmitted to the monitoring control board via the wiring board (BWB) on the back side of the plug-in unit, and the number or the identification number of the cabinet in which the plug-in unit to which the optical fiber cable is connected is mounted. A table that collects characters, numbers or characters that represent slot positions in the cabinet, numbers or characters that identify the connecting cabinet, and numbers or characters that represent slot positions in the cabinet net from the corresponding plug-in unit. And store it on the monitoring control panel. Further, the information may be sent to and stored in a remote monitoring control system through the monitoring control panel.
As a first means to display the plug-in unit slot on the front panel of the plug-in unit, place a rotary switch on the front panel of the plug-in unit and set the slot number of the plug-in unit Can be displayed. As a second means, an interface connector with a terminal can be arranged on the front panel of the plug-in unit, and connection information can be set and displayed from the terminal connected to the interface connector when the optical fiber cable is connected.
Prior to the above registration, before connecting the optical fiber cable on site, the connection information table is registered at the terminal of the remote monitoring control system, and the table and the optical fiber cable are registered at the time of connection. Can be automatically confirmed. If it is registered differently from the connection information registered in the remote monitoring control system, an alarm display lamp on the front panel of the plug-in unit can be turned on to notify the operator.
Also, according to the connection information table registered in advance, the indicator lamp on the front panel of the plug-in unit to be connected for each optical fiber cable blinks, and according to the guide, the maintenance person sees it and connects the optical fiber cable. be able to.
In addition, in order to verify whether the registered connection information table matches the actual connection, the optical output of the plug-in unit to which the newly connected optical fiber cable is connected is monitored based on the connection information table. When it is stopped by a stop signal from the control panel, the connection can be verified by detecting whether the optical input signal disconnection can be detected at the connection source.

According to the first solution of the present invention,
A plug-in unit for branching an optical signal input from an optical input connector arranged on the panel surface and outputting it from a plurality of optical output connectors arranged on the panel surface;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
In an optical signal distribution device comprising a monitoring control unit for monitoring and controlling the operating state of the plurality of plug-in units in the cabinet,
The plug-in unit is
Connection destination slot identification information (ID) indicating a slot position where a connection destination plug-in unit which is a connection destination of the other connection end of the optical fiber cable connected to the optical input connector is mounted, and the connection destination plug An interface for setting and displaying a connection destination device ID representing a cabinet accommodating an in-unit by a switch or an external terminal that is manually set and displayed;
A monitoring control interface (IF) that is connected to the switch or the interface and transmits and receives electrical signals to and from the monitoring control unit;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control IF of the connection source plug-in unit transmits the connection destination slot ID and the connection destination device ID converted into electrical signal information by the switch or the interface to the monitoring control unit,
The supervisory control board is provided with an optical signal distribution device for storing the transmitted information transmitted from the supervisory control IF.

According to the second solution of the present invention,
One optical signal is selected from the 0-system and 1-system optical signals input from the 0-system and 1-system optical input connectors arranged on the panel surface, and the selected optical signal is branched to be arranged on the panel surface. A plug-in unit that outputs from a plurality of optical output connectors;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
In an optical signal distribution device comprising a monitoring control unit for monitoring and controlling the operating state of the plurality of plug-in units in the cabinet,
The plug-in unit is
0-system connection-destination slot representing a slot position where a 0-system connection-destination plug-in unit that is a connection destination of the other connection end of the 0-system optical fiber cable connected to the 0-system optical input connector is mounted. Identification system (ID) and a 0 system connection destination device ID representing a cabinet that accommodates the connection destination plug-in unit are set and displayed by a 0 system switch or an external terminal that is manually set and displayed. Interface,
A 1-system connection destination that represents a slot position where a 1-system connection-destination plug-in unit that is a connection destination of the other connection end of the 1-system optical fiber cable connected to the 1-system optical input connector is mounted. A 1-system interface for setting and displaying a slot ID and a 1-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by a 1-system switch or an external terminal that is manually set and displayed; ,
A monitoring control interface (IF) connected to the 0 system and 1 system switches or the 0 system and 1 system interfaces and transmitting and receiving electrical signals to and from the monitoring control unit,

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control IF of the plug-in unit of the connection source includes the connection-destination slot IDs of the 0-system and the 1-system converted into electric signal information by the 0-system and 1-system switches or the 0-system and 1-system interfaces. The connection destination device ID is transmitted to the monitoring control unit,
The supervisory control board is provided with an optical signal distribution device for storing the transmitted information transmitted from the supervisory control IF.

According to the third solution of the present invention,
A plug-in unit for branching an optical signal input from an optical input connector arranged on the panel surface and outputting it from a plurality of optical output connectors arranged on the panel surface;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
A monitoring control unit for monitoring and controlling the operation state of the plurality of plug-in units in the cabinet;
In an optical signal distribution system including a monitoring control system connected to a plurality of the monitoring control units and performing communication constantly or periodically,

The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
A registration setting button for storing connection information in the connection information table of the monitoring control unit and transmitting the connection information to the monitoring control system,

The supervisory control system includes:
The connection information table and the management table of each of the monitoring control units are aggregated and stored in an aggregate connection information table and an aggregation management table, respectively.

The plug-in unit is
A connection destination slot ID indicating a slot position where a connection destination plug-in unit which is a connection destination of the other connection end of the optical fiber cable connected to the optical input connector is mounted, and the connection destination plug-in unit is accommodated An interface for setting and displaying a connection destination device ID representing a cabinet to be set and displayed by a switch or an external terminal that is manually set and displayed;
A supervisory control interface (IF) connected to the switch or the interface and transmitting and receiving electrical signals to and from the supervisory control unit;
An act lamp and a fail lamp controlled by the monitoring control IF;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control IF of the connection source plug-in unit transmits the connection destination slot ID and the connection destination device ID converted into electrical signal information by the switch or the interface to the monitoring control unit,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, and a connection For the previous plug-in unit, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,

The monitoring and control system registers the new or added or changed optical fiber cable connection information as a work table in the same format as the connection information table,
In accordance with the work table, the supervisory control system sequentially instructs the control unit defined by the equipment ID to display the equipment ID, slot ID, and act lamp on the plug-in units of the optical fiber cable connection source and connection destination. To display the act lamp provided in the plug-in unit,
An optical fiber cable is connected between the plug-in units indicated by the act lamp, the optical output connector, and the optical input connector, and the device ID and slot of the connected plug-in unit are connected to the switch or the interface of the connecting plug-in unit. When the ID is set and the registration setting button in the monitoring control unit of the connection source plug-in unit is operated, the connection destination set by the switch or the interface, the type of the connection source plug-in unit, the slot ID, and The device ID is notified from the monitoring control unit to the monitoring control system,
The monitoring control system includes the notified connection destination and connection source plug-in unit type and slot ID and device ID, and the connection destination and connection source plug-in unit type and slot ID registered in the work table. Check the device ID,
If they do not match due to collation, the monitoring control system notifies the device ID and slot ID of the connection source and connection destination plug-in units and the fail lamp display command to the monitoring control unit of the cabinet in which both plug-in units are mounted. Display the fail lamp of the plug-in unit of the connection destination and connection source,
On the other hand, if they match by collation, the monitoring and control system stops the act lamp and the fail lamp in the case of rework, so that the slot ID and device ID of the connection destination and the connection source plug-in unit and the lamp stop command are stopped. To the corresponding monitoring control unit, and the monitoring control system informs the connection destination and the type of the plug-in unit of the connection source, the slot ID, and the device ID, which are the connection information connected this time in the work table. An optical signal distribution system for adding to or updating the aggregated connection information table is provided.

According to the fourth solution of the present invention,
One optical signal is selected from the 0-system and 1-system optical signals input from the 0-system and 1-system optical input connectors arranged on the panel surface, and the selected optical signal is branched to be arranged on the panel surface. A plug-in unit that outputs from a plurality of optical output connectors;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
A monitoring control unit for monitoring and controlling the operation state of the plurality of plug-in units in the cabinet;
In an optical signal distribution system including a monitoring control system connected to a plurality of the monitoring control units and performing communication constantly or periodically,

The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
A registration setting button for storing connection information in the connection information table of the monitoring control unit and transmitting the connection information to the monitoring control system,

The supervisory control system includes:
The connection information table and the management table of each of the monitoring control units are aggregated and stored in an aggregate connection information table and an aggregation management table, respectively.

The plug-in unit is
0-system connection-destination slot representing a slot position where a 0-system connection-destination plug-in unit that is a connection destination of the other connection end of the 0-system optical fiber cable connected to the 0-system optical input connector is mounted. A 0-system interface for setting and displaying an ID and a 0-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by using a 0-system switch or an external terminal that is manually set and displayed;
A 1-system connection destination that represents a slot position where a 1-system connection-destination plug-in unit that is a connection destination of the other connection end of the 1-system optical fiber cable connected to the 1-system optical input connector is mounted. A 1-system interface for setting and displaying a slot ID and a 1-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by a 1-system switch or an external terminal that is manually set and displayed; ,
A monitoring control interface (IF) connected to the 0-system and 1-system switches or the 0-system and 1-system interfaces, and for transmitting and receiving electrical signals to and from the monitoring control section;
An act lamp and a fail lamp controlled by the monitoring control IF;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control IF of the plug-in unit of the connection source includes the connection-destination slot IDs of the 0-system and the 1-system converted into electric signal information by the 0-system and 1-system switches or the 0-system and 1-system interfaces. The connection destination device ID is transmitted to the monitoring control unit,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, connection source type, connection source device ID and connection slot ID, 0 For the plug-in unit of the connection destination of the system, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, 1 For the plug-in unit of the connection destination of the system, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,

The monitoring and control system registers the new or added or changed optical fiber cable connection information as a work table in the same format as the connection information table,
In accordance with the work table, the supervisory control system sequentially instructs the control unit defined by the equipment ID to display the equipment ID, slot ID, and act lamp on the plug-in units of the optical fiber cable connection source and connection destination. To display the act lamp provided in the plug-in unit,
An optical fiber cable is connected between the plug-in units indicated by the act lamp, the optical output connector, and the optical input connector, and the device ID and slot of the connected plug-in unit are connected to the switch or the interface of the connecting plug-in unit. When the ID is set and the registration setting button in the monitoring control unit of the connection source plug-in unit is operated, the connection destination set by the switch or the interface, the type of the connection source plug-in unit, the slot ID, and The device ID is notified from the monitoring control unit to the monitoring control system,
The monitoring control system includes the notified connection destination and connection source plug-in unit type and slot ID and device ID, and the connection destination and connection source plug-in unit type and slot ID registered in the work table. Check the device ID,
If they do not match due to collation, the monitoring control system notifies the device ID and slot ID of the connection source and connection destination plug-in units and the fail lamp display command to the monitoring control unit of the cabinet in which both plug-in units are mounted. Display the fail lamp of the plug-in unit of the connection destination and connection source,
On the other hand, if they match by collation, the monitoring and control system stops the act lamp and the fail lamp in the case of rework, so that the slot ID and device ID of the connection destination and the connection source plug-in unit and the lamp stop command are stopped. To the corresponding monitoring control unit, and the monitoring control system informs the connection destination and the type of the plug-in unit of the connection source, the slot ID, and the device ID, which are the connection information connected this time in the work table. An optical signal distribution system for adding to or updating the aggregated connection information table is provided.

According to the present invention, the connection information of the optical fiber cable between the plug-in units is displayed on the panel (front panel, etc.) or the panel (front panel, etc.) of the plug-in unit to be connected during the optical fiber cable connection work. Since connection information that is displayed on a terminal such as a connected personal computer and that matches the display content is automatically notified to the monitoring control panel and the remote monitoring control system, the operation is facilitated and erroneous connection is less likely to occur.
In addition, according to the present invention, an optical fiber that automatically turns on and displays the LED lamp on the front panel of the connection unit of the optical fiber cable and the plug-in unit of the connection source from the monitoring and control system can be accurately connected. This makes it possible to work without error and to prevent accidental disconnection of the optical fiber cable connection during operation. Further, according to the present invention, when the maintenance person registers the connection information of the connected optical fiber cable, it automatically determines whether the registration information matches the connection information table registered in the monitoring control system in advance. If it is judged and wrong, it can be notified so that the wrong work can be prevented. According to the present invention, the optical output of the plug-in unit on the optical output side is stopped for the newly connected optical fiber cable based on the registered connection information table, and the optical input is performed on the input side. By detecting the disconnection, it is possible to confirm whether the optical fiber cable is actually connected correctly, and it is possible to prevent the service being operated from being damaged.
As described above, according to the present invention, when the erroneous connection does not occur, the failure propagation is accurately grasped by the monitoring control panel and the monitoring control system. For example, a failure occurs in the plug-in unit, and the light output is interrupted. If the input power failure is a downstream plug-in unit connected to the optical output by an optical fiber cable and used as an optical input, monitor the control panel, or monitor the remote control It can be determined by the system and the faulty plug-in unit can be identified accurately.

The functional block diagram of the optical amplifier panel for optical image signal distribution. The functional block diagram of the optical switch branch board for optical video signal redundant switching. The functional block diagram of the optical amplifier panel for optical video signal relay. The figure of the front panel example 1 of the optical amplifier board for video signal distribution, and the optical switch branch board for optical video signal redundancy switching. The system block diagram which comprised the optical video signal distribution apparatus of the building C of FIG. The system block diagram which comprised the optical video signal distribution apparatus of the building A of FIG. The figure of an example of a connection information table. The figure of an example of a connection information table. The figure of an example of a plug-in unit management table. The figure of an example of a plug-in unit management table. The figure which shows an example of the inside and external appearance of the optical video signal distribution apparatus of Fig.3 (a). The figure which shows an example of the external view example of the optical video signal distribution apparatus of FIG.3 (b). The flowchart of an optical fiber cable connection operation | work. The flowchart which verifies an optical fiber cable connection. FIG. 7 is a sequence diagram of the flowchart of FIG. FIG. 7 is a sequence diagram of the flowchart of FIG. The figure of the front panel example 2 of the optical amplifier for video signal distribution, and the optical switch branching board for optical video signal redundancy switching. FIG. 2 is a diagram of an example CATV FTTH system. The figure of the example of a cabinet of the optical video signal distribution apparatus of FIG. The block diagram of the memory of a monitoring control board. The block diagram of the memory of a monitoring control system.

1. Plug-in unit

In the embodiment of the optical image distribution device of the present invention described below, the function block diagram, the plug-in unit having the functions shown in FIGS. 1 (a), 1 (b) and 1 (c) is accommodated.

1-1. Distribution Optical Amplification Panel The plug-in unit having the function shown in the functional block diagram of FIG. 1A is an optical video signal distribution optical amplification panel. The optical input optical video signal input from the optical input connector 1 on the front panel of the plug-in unit is amplified by the fiber optical amplifier 2 and then branched by the optical branching (8 branches in this example) 3 to the front panel. Output from the attached optical output connector 4. Note that the optical video signal of the present embodiment is an optical signal whose optical intensity has been modulated by the video modulation signal, and even when there is no video signal, the optical signal is intensity-modulated by the carrier signal and always has a constant average value light. Has an output level. The supervisory control interface unit 5 detects an abnormal operation alarm such as an optical input interruption and an optical output abnormality detected in the fiber optical amplifier 2, and from the plug-in connector 6 through a wiring board in the apparatus to be described later. The electric signal is transmitted to the monitoring control panel in the apparatus. Conversely, a signal is sent from the monitoring control panel to the fiber optical amplifier 2 via the wiring board and the monitoring control interface, and the output is stopped. Further, by connecting the plug-in connector 6 to the wiring board, power is supplied to the optical video signal distribution optical amplifier board. The thumb rotary switch can manually set the display number or character, and changes the contact combination of the plurality of contacts according to the display character or number. The connection information of the optical fiber cable connected to the optical input connector 1 from the front panel side is set in the two thumb rotary switches 7 and 2 on the front panel. That is, the number or letter indicating the slot position of the plug-in unit that mounts the optical output connector to be connected and the number or letter indicating the device (cabinet) that accommodates the plug-in unit are manually entered by the thumb rotary switch 7. Set and display. The displayed number or character information is converted into electrical signal information using a combination of contact points of the thumb rotary switch 7 and transmitted from the plug-in connector 6 to the monitoring control board via the wiring board in the apparatus. Is done. Further, when the plug-in unit is mounted, the type of the self-plug-in unit and information on the slot position where the plug-in unit is mounted are also sent from the monitoring control interface 5 via the plug-in connector 6 and the wiring board in the apparatus. Is transmitted to. Information on the slot position where the own plug-in unit is mounted is converted into a combination in which a plurality of connection pins of the plug-in connector 6 are connected to the ground on the wiring board and recognized by the monitoring control interface 5. As for the type of the plug-in unit, a code for distinguishing the type is stored in the monitoring control interface 5. The ACT lamp 8 and the FAIL lamp 9 of the LED lamps on the front panel are controlled to be turned on by the monitoring control panel via the wiring board, the plug-in connector 6 and the monitoring control interface unit 5. When a remote monitoring control system or monitoring control panel connected to the monitoring control panel via a communication line puts the plug-in unit into service operation, the ACT lamp is turned on, and when the failure of the plug-in unit is judged, the FAIL lamp is turned on. Let The LED lamp is also blinked during the optical fiber cable connection operation described below.
FIG. 2A is an example of a front panel of the optical image signal distribution optical amplifier panel of FIG. 1A described above. Of the two installed thumb rotary switches 7, the number or letter indicating the device (cabinet) to which the other end of the optical fiber cable is connected is on the left side, and the plug-in unit of the other end is on the right. Set the number or character that indicates the slot location that is installed.

1-2. Redundant switching optical switch branch board The plug-in unit having the function shown in FIG. 1B is an optical video signal redundant switching optical switch branch board. The 0-system optical input optical video signal and the 1-system optical input optical video signal are input from two optical input connectors 10 on the front panel of the plug-in unit. In the optical switch 11, one optical input video signal is selected, and when an abnormality occurs in the optical signal, it is detected and switched to the other optical input video signal. Also, the optical output is stopped by the optical ON / OFF switch. In the optical branch (four branches in this example) 12, the optical input video signal selected by the optical switch 11 is branched and output to the optical output connector 13 on the front panel. The monitoring control interface unit 14 transmits an operation abnormality alarm and an optical signal abnormality of the optical switch 11 from the plug-in connector 18 to the monitoring control panel via a wiring board to be described later. Conversely, a signal is sent from the supervisory control board to the ON / OFF switch of the optical switch via the wiring board and the supervisory control interface, and the optical output to the optical output connector 13 is stopped. The four thumb rotary switches 15 on the front panel set connection destination information of optical fiber cables connected to the 0-system and 1-system optical input connectors 10 from the front panel side. That is, the number or letter indicating the slot position of the plug-in unit that mounts the optical output connector to be connected and the number or letter indicating the device (cabinet) that accommodates the plug-in unit are manually entered by the thumb rotary switch 15. Set and display. As with the optical image signal distribution optical amplifier panel, the display number or character information is transmitted to the supervisory control panel. In addition, when the plug-in unit is mounted, the type of the self-plug-in unit and the information on the slot position where the plug-in unit is mounted are also monitored from the monitor control interface 14 via the plug-in connector 18 and the wiring board in the same device. Is transmitted to. The information on the slot position where the own plug-in unit is mounted is converted into a combination in which a plurality of connection pins of the plug-in connector 18 are connected to the ground on the wiring board and recognized by the monitoring control interface 14. As for the type of the plug-in unit, a code for distinguishing the type is stored in the monitoring control interface 14. The ACT lamp 16 and the FAIL lamp 17 of the LED lamp on the front panel are similar to the above-described optical amplifying panel for distributing the optical video signal through the wiring board, the plug-in connector 18 and the monitoring control interface unit 14 by the monitoring control board. The lighting and blinking are controlled.
FIG. 2B is an example of the front panel of the plug-in unit of FIG. 1B described above. The upper two of the four mounted rotary switches are used to display the connection destination of the 0-system optical input connector. The left side is the number or letter that indicates the connected device (cabinet), and the right side is the connection destination plug. A number or a letter indicating the slot in which the in-unit is mounted is displayed, and the lower two are for displaying the connection destination of the 1-system optical input connector.

1-3. The optical amplifier board for relay The plug-in unit having the function shown in the functional block diagram of FIG. 1C is an optical amplifier board for optical video signal relay. Similar to the optical video signal distribution optical amplifier panel described above, the optical input optical video signal input from the optical input connector 19 on the front panel of the plug-in unit is amplified by the fiber optical amplifier 20 and then optically branched (main In the example, the light is branched at 21) and output from the optical output connector 22 attached to the front panel. The supervisory control interface unit 23 detects an operation abnormality alarm such as an optical input interruption and an optical output abnormality detected in the fiber optical amplifier 20, and from the plug-in connector 26 via a wiring board in the apparatus described later. The electric signal is transmitted to the monitoring control panel in the apparatus. Conversely, a signal is sent from the monitoring control panel to the fiber optical amplifier 20 via the wiring board and the monitoring control interface, and the optical output is stopped. However, in the optical amplifier for relay, the counterpart connection destination of the optical fiber cable connected to the optical input connector 19 is a remote optical video distribution apparatus or the like, and the connection destination information is not set and displayed on the thumbwheel switch. In addition, when the plug-in unit is mounted, the type of the self-plug-in unit and information on the slot position where the plug-in unit is mounted are also sent from the monitoring control interface 23 via the wiring board in the same device as the plug-in connector 26. Is transmitted to. The information on the slot position where the own plug-in unit is mounted is converted into a combination in which a plurality of connection pins of the plug-in connector 23 are connected to the ground on the wiring board and recognized by the monitoring control interface 26. For the types of plug-in units, a code for distinguishing the types is stored in the monitoring control interface 23. The ACT lamp 27 and FAIL lamp 28 of the LED lamp on the front panel are similar to the above-described optical amplifying panel for distributing optical video signals through the wiring board, the plug-in connector 18 and the monitoring control interface unit 23 by the monitoring control board. ON / FLASH controlled

2. System (Building C)

3A is a functional block diagram described above, and the optical video signal distribution device of the building C of FIG. 8 with the plug-in unit having the functions of FIGS. 1A, 1B, and 1C mounted thereon. FIG. In the optical video signal distribution device of FIG. 3A, the eight optical video signal distribution optical amplifier panels 29 described in FIGS. 1A and 2A are provided, and FIGS. 1B and 2B. 2) and two optical video signal relay switching optical amplifiers 31 described with reference to FIG. 1 (c) are accommodated, and each is connected to the wiring board 32. Connected. The supervisory control board 33 is connected to the wiring board 32 and is connected to the supervisory control interface of the optical video signal distribution optical amplifier board 29, the optical video signal redundancy switching optical switch branch board 30, and the optical video signal relay optical amplifier board 31. Connecting.
The monitoring control panel 33 includes a registration setting button 35, a communication function unit 36, a central processing unit (CPU) 37 including an alarm processing / LED lamp control unit, and a memory 38. The monitoring control system 301 includes a communication control unit 302, a central processing unit (CPU) 303, and a memory 304.

FIG. 10 shows a configuration diagram of the memory 38 of the monitoring control panel 33.
FIG. 11 shows a configuration diagram of the memory 304 of the monitoring control system 301.
The memory 38 of the monitoring control panel 33 includes a connection information table and a plug-in unit management table for plug-in units mounted on the device itself. Further, the memory 304 of the monitoring control system 301 includes an aggregated connection information table and plug-in unit management table for plug-in units mounted on a plurality of devices of the monitoring control panel 33 connected to the own system, Includes work table. The work table has the same format as the connection information table. Details of the connection information table and plug-in unit management table, and the aggregated connection information table and plug-in unit management table will be described later.

2-1. Monitoring control panel The monitoring control panel 33 collects operation abnormality alarms and mounting information (slot position, type of plug-in unit) of each plug-in unit through connection with the monitoring control interface. These pieces of information are stored in the memory 38 as a plug-in unit management table. As described above, the type of plug-in unit installed in each slot position, the slot position information, and the operation abnormality alarm are set from the monitoring control interface 33 of the plug-in unit after mounting the plug-in unit. Is notified via the wiring board 32. An example of the plug-in unit management table will be described later with reference to FIG. Wiring 34 of the optical fiber cable between the plug-in units is performed between the optical input / output connectors on the front panel of the apparatus, and the configuration of the building C in FIG. This wiring information (connection information) is set by the thumb rotary switch of the plug-in unit 29.30, sent from the monitoring control interface to the monitoring control board 33 via the wiring board 32, and registered on the front panel of the monitoring control board. The setting button 35 is input and registered in the monitoring control panel 33 and the remote monitoring control system when the apparatus maintenance worker or the installation operator pushes down the optical fiber cable when wiring. The individual connection information to be registered is stored in the memory 38 of the monitoring control panel 33 and the memory 304 of the monitoring control system 301 as a connection information table as will be described later with reference to FIG. The monitoring control panel 33 stores the connection information table in association with the number or character indicating the connection destination / connection source device / slot position and the type of the plug-in unit for each connection as follows.
FIG. 3C shows a connection information table in the memory 38 of the monitoring control panel 33. For each connection number 320, the plug-in unit of the plug-in unit of the optical fiber cable having the thumb rotary switch to be set is shown. In-unit type (connection source type 321), mounted device (cabinet) number (connection source device number 322), device (cabinet) slot position (connection source slot number 323), and optical fiber cable Plug-in unit type (connection destination type 324), mounted device (cabinet) number (connection-destination device number 325), device (cabinet) slot position (connection-destination slot number) 326) is connection information of one connection. The connection source device number 322 is set and stored in the monitoring control panel 33 with a DIP switch or the like before being mounted on the device. As the connection destination device number, the value set by the thumb rotary switch of the connection source plug-in unit is notified to the monitoring control panel 33. Connection numbers 1 to 12 in the connection information table represent information on the wiring 34 of the optical fiber cable in FIG. The connection number 320 is a predetermined number, and can be appropriately determined by the monitoring control panel 33 or the monitoring control system 301 at the time of new / addition / change, for example. The types 321 and 324 of the plug-in units are as follows: A is the optical video signal distribution optical amplifier board 29, B is the optical video signal redundancy switching optical switch branch board 30, and C is the optical video signal relay optical amplifier board 31. The number of the device (cabinet) is 1.
FIG. 3E shows a plug-in unit management table in the memory 38 of the monitoring control board 33. The device number 327 is the same as the connection source device number 322, and is a value stored in the monitoring control panel 33 before being mounted on the device. The plug-in unit type 329 mounted in each slot number 328, service information 330, and operation abnormality alarm information 331 are used as one plug-in unit management information. The service information 330 is information indicating whether the plug-in unit of the slot is in service operation. This is set in the monitoring control system 301 described later from the terminal and notified to the monitoring control panel 33. In this example, 1 represents operation and 0 represents non-operation. The plug-in unit type 329 and the operation abnormality alarm information 330 are notified from the monitoring control interface of each plug-in unit to the monitoring control board 33 via the wiring board 32 as described above. In the table of this example, 1 indicates that there is an operation abnormality alarm and 0 indicates that there is no operation abnormality alarm.
The communication control unit 302 of the remote monitoring control system 301 is connected to the communication function unit 36 of the monitoring control panel 33 and communicates monitoring control information constantly or periodically. As described above, the connection information table and the plug-in unit management table of each device are aggregated and stored in the memory 304. FIGS. 3D and 3F are examples of the consolidated connection information table and plug-in unit management table, which have the same format as FIGS. 3C and 3E, respectively, and will be described later. When there is a change in the connection information table and the plug-in unit management table in the memory 38 of the monitoring control panel 33 of each aggregated apparatus, the monitoring control system 301 is immediately notified and the table in the memory 304 is updated. In the CPU 37 including the alarm process of the monitoring control panel 33 of each device (cabinet) and the LED lamp control unit, based on the optical fiber cable wiring information and the collected operation abnormality alarm of each plug-in unit 29, 30, 31 Masks secondary alarms that are propagated from an alarm (invalidation of alarms) and identifies faulty plug-in units. For example, if the optical switch branch board 30 for redundant switching of the optical video signal fails and the optical output is cut off, the alarm collected by the supervisory control board 33 is the optical switch of the optical switch branch board 30 for redundant switching of the optical video signal. The optical input disconnection detected by the fiber optical amplifier 2 of the optical video signal distribution optical amplifier panel 29 to which the optical fiber cable is connected by using the optical output of the optical switch branch board 30 for switching the optical video signal redundancy as the input. It is an alarm. These two alarms are determined based on the information that the optical fiber cable is connected between both plug-in units, and the CPU 37 including the alarm processing and LED control unit determines that the cause is a failure of the optical switch. Mask the optical input interruption alarm of the optical video signal distribution optical amplifier panel 29 which is a typical alarm (invalidation of the alarm), and identify the faulty plug-in unit as the optical video signal redundancy switching optical switch branch board 30 The FAIL lamp of the fault plug-in unit is turned on from the monitoring control interface. Since the monitoring control system 301 is notified of the plug-in unit management information and connection information table of each device (cabinet), when the connection of the optical fiber cable crosses the device (cabinet), its central processing unit ( CPU) 303 performs alarm masking (alarm invalidation) and failure plug-in unit identification as described above, and notifies the monitoring control panel 33 of the corresponding device via the communication control unit 302 for identification. The FAIL lamp of the fault plug unit is turned on from the monitoring control interface.

2-2. External View of Plug-in Unit FIG. 4 is a diagram showing an example of the internal and external appearance of the optical video signal distribution device of FIG. 3A described above. In this way, the plug-in unit is mounted on the front side of the apparatus with the wiring board 41 arranged behind the back, and connected by the plug-in connector 43. In the present embodiment, the slot numbers in which the plug-in units are installed are 1 to 12 from the left, the optical video signal relaying optical amplifying board 31 is assigned to slots 1 and 2, and the optical video signal redundancy switching is assigned to slots 3 and 4. The optical switch branch board 30 and the slots 5 to 12 are mounted with the optical image signal distribution optical amplifier board 29 and the monitoring control board 33 on the right side of the slot 12. However, any of the above three types of plug-in units may be mounted in the slots 1 to 12 according to the application configuration. The figure shows the connection of the optical fiber cable between the plug-in unit of the optical amplifying panel for repeating the optical video signal in slots 1 and 2 and the plug-in unit of the optical switch branching board for redundant switching of the optical video signal in slot 3. At this time, the display of the thumb rotary switch of the optical switch branch board for optical video signal redundancy switching in slot 3 is device (cabinet) number 1, the upper two are “1”, “1” and the lower two are “1”. “2”. Also, the connection of the optical fiber cable of the optical switch branch board for switching the video signal redundancy in slot 3 and the optical amplifier board for distributing the optical video signal in slot 5 is shown. At this time, the display of the thumb rotary switch is “1”. 3 "".

3. System (Building A)

FIG. 3B is a functional block diagram described above, and the optical video signal distribution device of the building A of FIG. 8 is installed with the plug-in unit having the functions of FIGS. 1A, 1B, and 1C. FIG. The optical video signal distribution device of FIG. 3A is the basic device 44, and the optical video signal distribution device equipped with the optical video signal distribution optical amplifying board 29 having the function of FIG. It is the structure to do. The optical image signal distribution optical amplifier board 29 mounted on the extension device 45 receives the optical output of the optical video signal distribution optical amplifier board mounted in the slots 5 to 12 of the basic device 44.
Connection numbers 1 to 48 in the connection information table in FIG. 3D represent information on the optical fiber cable wiring 306 in FIG. 3B that the monitoring control system 301 has, and the type of plug-in unit is optical The optical amplifier board 29 for distributing video signals is A, the optical switch branch board 30 for redundant switching of optical video signals is B, the optical amplifier board 31 for relaying optical video signals is C, the device number of the basic device is 1, and the device of the extension device The numbers are 2, 3, and 4.
FIG. 3F is a plug-in unit management table for the basic device 44 and the expansion device 45 in FIG. 3B, and the tables of the respective devices are aggregated and stored in the memory 304 of the monitoring control system 301.
As described above, FIG. 10 shows a configuration diagram of the memory 38 of the monitoring control panel 33.
FIG. 11 shows a configuration diagram of the memory 304 of the monitoring control system 301.

FIG. 5 shows a front view of the basic device 44 and the expansion device 45 and the connection of the monitoring control system. The upper device is the basic device 44 and the lower device is the expansion device 45. In the expansion device 44, the optical amplifier 29 for distributing the optical video signal is mounted in the slots 1-12. In the figure, an optical fiber cable connection example between the optical amplifying panel 29 for distributing optical video signals mounted in the slot 5 of the basic device (cabinet) 44 and the slot 1 of the additional device (cabinet) 45 is shown in the figure. The display number of the thumb rotary switch of the optical video signal distribution optical amplifier panel in slot 1 of the extension device 44 is “1” “5”. This connection information is transmitted from the control panel 33 of the extension device (cabinet) 45 to the remote monitoring control system 301. For example, when the optical video signal distribution optical amplifying board 29 in the slot 5 of the basic device 44 fails due to the interruption of the optical output, the optical video signal distribution optical amplification board 29 in the slot 1 of the downstream additional device (cabinet) 45 is used. An optical input interruption is detected by the fiber optical amplifier 2. In this case, the central processing unit (CPU) 303 of the supervisory control system 301 masks the optical input interruption alarm so that the optical image signal distribution optical amplifier panel 29 of the expansion device (cabinet) 45 is not determined as a failure. The communication control unit 302 is connected to the monitoring control board 33 of the extension device (cabinet) 45 so that the FAIL lamp is not turned on in the optical amplifier panel 29 for distributing the optical video signal in the slot 1 of the extension device (cabinet) 45. Notify via
According to the optical video signal distribution device described above, the connection information table of the optical fiber cable is registered in the monitoring control panel 33 and the remote monitoring control system 301 by the thumb rotary switch, and the number of users is changed. Even if plug-in units and devices are added in any configuration corresponding to the above, it is possible to grasp the connection information of the optical fiber cable, thereby making it possible to appropriately identify the failure site.

4). Connection work

4-1. New / Addition / Change

Connection information to be newly added / added / changed in the monitoring control system 301 is registered in advance as a work table and collated with the information registered at the time of operation, so that an error or disconnection of the optical fiber cable connection work can be prevented. . This will be described with reference to the flowchart of FIG. The flowchart in FIG. 6A is the optical video signal distribution apparatus according to the present embodiment described above, and a new connection of an optical fiber cable connected between plug-in units in the apparatus or an addition due to a change in the number of users accommodated. It is a control flow of the central processing unit 303 of the monitoring control system 301 at the time of change connection work. First, in S1, the apparatus administrator uses the terminal 305 of the remote monitoring and control system 301 to connect the optical fiber cable connection information to be newly or additionally changed from the connection information described in FIGS. 3C and 3D. A work table is input and registered in the memory 304 separately from the connection information table in the same format as the table.
At this time, if there are plug-in units that are newly installed or additionally installed, the worker installs them in the cabinet in advance at the installation location of the apparatus. In the monitoring control panel 33, when the operator installs the plug-in unit, the plug-in unit management table is updated as described above, and the slot position, device number, and type of the installed plug-in unit are added. That is, by using the device number set in advance in the monitoring control panel 33 (CPU 37), the monitoring control panel 33 (CPU 37) receives the slot position, type, and abnormal operation alarm from the monitoring control interface of each plug-in unit. Information can be obtained, and each of these pieces of information (device number 327, slot number 328, plug-in unit type 329, operation abnormality alarm information 331) can be stored in the plug-in unit management table. Since the service information 330 is notified from the monitoring control system 301 to the monitoring control board 33 constantly or periodically, the monitoring control board 33 can store the information. Further, as described above, the communication control unit 302 of the remote monitoring control system 301 is connected to the communication function unit 36 of the monitoring control panel 33, and communicates monitoring control information constantly or periodically. The connection information table and the plug-in unit management table of each device such as 3 (c) (e) are collected and stored in the memory 304 as shown in FIGS. 3 (d) and 3 (f), for example.
The central processing unit 303 of the monitoring control system 301 refers to the memory 304 and collates and matches the plug-in unit type, slot position, and device number in the registered work table with information in the plug-in unit management table. If it is confirmed that it is, the process proceeds to S2. If they are different, the supervisory control panel 33 must be notified to blink the fail lamp of the wrong plug-in unit, the operator must be notified, and it must be correctly mounted. In S2, in accordance with the registered work table information, the supervisory control system 301 first has two plug-in unit devices for input (connection source) and output (connection destination) of the optical fiber cable to which the connection number 1 is connected. The number, slot position, type and command for blinking the ACT lamp are notified to the monitoring control board 33 of the corresponding device.
The worker who connects the optical fiber cable connects the optical fiber cable between the optical output connector and the optical input connector of the plug-in unit blinking at the installation location of the apparatus. The operator recognizes the entire work information in advance and determines whether the connector to be connected is an input connector or an output connector, or the monitoring control panel 33, for example, an input plug-in unit and an output plug-in By changing the blinking cycle of the unit, the operator can determine whether the connector to be connected is an input connector or an output connector. After connecting the optical fiber cable, the operator must connect the device number of the plug-in unit to which the optical fiber cable is connected to the optical output connector to the thumb rotary switch of the connection source plug-in unit connected to the optical input connector. Alternatively, a character and its slot number or character are set, and the registration setting button 35 in the monitoring control unit 33 of the device on which the connection source plug-in unit is mounted is pushed down. By depressing the registration setting button, the connection destination set by the thumb rotary switch, the plug-in unit type and mounting slot position of the connection source, and device number information are notified to the monitoring control panel 33 and the remote monitoring control system. 301 (S3) and stored in the connection information tables of the memory 38 and the memory 304, respectively, the monitoring control system 301 transitions to S4. The monitoring control panel 33 is set from the monitoring control interface of the connection source plug-in unit by the slot position (connection source slot number 323) and type (connection source type 321) of the plug-in unit set therein, and a rotary switch. The connection destination plug-in unit slot position (connection destination slot number 326) and device number (connection destination device number 325) are received. Further, the monitoring control panel 33 refers to the plug-in unit management table to search for a device number corresponding to the received connection source slot number and type, or uses a device number set in the monitoring control panel 33 in advance. Thus, the connection source device number 322 can be obtained. Furthermore, the monitoring control panel 33 can obtain the connection destination type 324 based on the type corresponding to the connection destination slot number and the device number by referring to the plug-in unit management table. The monitoring control board 33 registers the connection information 320 to 326 of the connection number n = 1 in the connection information table and transmits it to the remote monitoring control system 301.
In S4, the supervisory control system 301 sends the notified connection destination to the connection number, the type of the plug-in unit, the mounting slot position, the device number information of the connection source, and the operation of the optical fiber cable registered before the operation. If the tables are collated and they do not match, the device number, slot position, and FAIL lamp blinking command of the connection source plug-in unit and the connection destination plug-in unit that have the set thumb rotary switch are monitored and controlled by the corresponding device. 33 is notified (S7), and the FAIL lamps of the connection destination and connection source plug-in units are blinked. After confirming this blinking, the operator confirms the connection of the optical fiber cable and registers the setting of the thumb rotary switch again. By pushing down the registration setting button, the connection destination, the connection source, the type of plug-in unit, the mounting slot position, and the device number information are stored in the monitoring control panel 33 and the remote monitoring control system 301 as described above. Alternatively, when the verification is notified and the collation matches in S3 and S4, the supervisory control system 301 stops the blinking of the ACT lamp and the FAIL lamp in the case of reworking. The mounting slot position, device number information and lamp blinking stop command are notified to the corresponding monitoring control panel 33 (S5). After the notification, in S6, the monitoring control system 301 adds the registration information of the connection number n = 1 in the work table to the end of the connection information table, and proceeds to S8. If the connection is not an addition but a change, the changed part is overwritten and the process proceeds to S8. In S8, the monitoring control system determines whether or not there is an optical fiber cable connection work of the next connection number 2 in accordance with the work table registered in S1, and if there is, the optical fiber of the next connection number 2 The ACT lamp of the plug-in unit to which the cable is connected is shifted to S2 within a predetermined time determined in advance, and a blinking display is notified to the monitoring control panel 33 (S2). The above is repeated until the connection of the optical fiber cables of all the connection numbers is completed, and when the worker confirms that blinking for prompting a new connection does not start within a certain time, the worker finishes the work. If the work is completed according to this flowchart, the registered connection information table and the work table registered in the remote monitoring and control system before the start of the connection work match, so the incorrect connection and registration are prevented. can do.
FIG. 6C is a sequence diagram showing the exchange of processing among the plug-in unit, the monitoring control unit, and the monitoring control system in the flowchart of FIG. The part enclosed by the broken line in the sequence diagram is the work of the operator. Looking at this, the operator connects the cable according to the blinking of the ACT lamp, and notifies the monitoring control unit and the monitoring control system of the connection destination slot number and device number with the thumb rotary switch in the connection source plug-in unit. If there is an error, the apparatus notifies the user by blinking the FAIL lamp. While correcting this, it can be seen that the worker should work until there is no instruction to connect the optical fiber cable due to blinking of the ACT lamp. In addition, since the connection of the optical fiber cable is also between devices (cabinets), the ACT lamp and the FAIL lamp are controlled to blink from the monitoring control system.

4-2. Test Fig. 6 (b) is a flowchart added to Fig. 6 (a). When the operator registers and sets the optical fiber cable connection with the thumb rotary switch, the actual optical fiber cable connection matches. It is for connecting while testing. In FIG. 6 (a), an operator connects an optical fiber cable between S2 and S3 between plug-in units with blinking ACT lamps, thereby preventing incorrect connection. In FIG. 6B, an operation of electrically confirming and verifying the connection of the optical fiber cable is added to further eliminate an artificial connection error. The flowchart in FIG. 6B is inserted between FIG. 6A and S2 and S3 (under the transition from S7). The supervisory control system 301 notifies the supervisory control board 33 of the connection destination and the slot position of the connection source and the device number in order to blink the ACT lamp of the plug-in unit to be connected in S2 of FIG. After a predetermined time required for the operator to connect the cable, the plug-in unit management table is referred to in S9, and the light of the plug-in unit of the connection source is determined based on the slot position and device number of the connection source plug-in unit. Check if there is an input interruption alarm. Note that the monitoring control unit 33 controls the plug-in unit to be connected so that the optical output is turned on when the plug-in unit is mounted in the cabinet. When the monitoring control system 301 confirms that there is a light input interruption alarm in S9, the monitoring control system 301 transitions to S7 in FIG. 6 (a) and turns on the fail lamp of the plug-in unit of the connection destination connection source. A command for blinking is notified to the monitoring control unit 33 of the corresponding device, and the operator is urged to reconnect the optical fiber cable.
When the monitoring control system 301 confirms that there is no light input interruption alarm of the plug-in unit of the connection source in S9, the monitoring control system 301 transits to S10, and the plug-in unit management table Referring to Fig. 4, it is confirmed whether the plug-in unit at the connection destination is in service operation based on the slot position and device number of the connection-destination plug-in unit. In S10, when the monitoring control system confirms that the connection destination plug-in unit is in operation, the process proceeds to S15, and if the connection destination connection source FAIL lamp in S7 flashes, A command to stop is notified to the corresponding monitoring control board 33, the process proceeds to S3 in FIG. 6A and the flowchart, and connection information (connection destination / original device number of connection number n, slot) Wait for receipt of the number and plug-in unit type. If it is confirmed that it is not in operation, the supervisory control system transits to S11 and notifies the corresponding supervisory control board 33 of a command to stop the plug-in unit optical output of the connection destination. When the connected plug-in unit is in operation, its optical output is branched into multiple optical outputs, so if you stop the optical output of the plug-in unit that is in operation, other branched optical outputs are also stopped Service will be interrupted. For this reason, when the connected plug-in unit has a light output in operation, the flow returns to S3 without making a transition to S11. If it is not in operation, after stopping the optical output in S11, the supervisory control system 301 transitions to S12, and checks the plug-in unit management table for the presence or absence of light input interruption of the connection source plug-in unit. In addition, since the light output is stopped in S11, an input interruption alarm is output in normal operation (becomes “present”). When the monitoring control system 301 confirms that there is no input disconnection alarm of the connection destination plug-in unit in S12 (abnormal state), the monitoring control system 301 transitions to S14 and turns on the optical output of the connection destination plug-in unit. The command is notified to the monitoring control panel 33, and the process proceeds to S7. When the monitoring control system confirms that there is a light input interruption alarm of the connection source plug-in unit by looking at the plug-in unit management table in S12 (normal state), the monitoring control system transitions to S13. Then, a command to turn on the optical output of the connection destination plug-in unit is notified to the monitoring control panel 33, and if there is a blinking FAIL lamp of the connection destination or connection source plug-in unit in S7, this is stopped. The supervisory control board 33 is notified of the command, and the process proceeds to S3 in FIG. 6A and the flowchart, and the connection information from the supervisory control board 33 (connection destination / original device number of connection number n, slot number, plug-in unit) Wait for the reception of the seed.
FIG. 6D is a sequence diagram showing the exchange of processing among the plug-in unit, the monitoring control unit, and the monitoring control system in the flowchart of FIG. The part enclosed by the broken line in the sequence diagram is the work of the operator. By adding the flow of FIG. 6 (b) to the flow of FIG. 6 (a), the operator is notified by blinking of the FAIL lamp when there is an error in the work at the time of connecting the cable. . If there is no error, the connected information is notified from the plug-in unit to the monitoring control panel 33 and the monitoring control system 301 by the thumb rotary switch (S3). It is notified by flashing. Confirmation is performed with respect to the connection of the optical fiber cable and the setting of the connection information, respectively, and the operator performs the work until there is no instruction to connect the optical fiber cable due to blinking of the ACT lamp, while confirming and correcting the work. Also in this flow, since the connection of the optical fiber cable is also between the devices (cabinets), the monitoring control system 301 controls the blinking of the FAIL lamp.
In the above description, the configuration example of the optical video signal distribution device in which the thumb rotary switch is mounted on the front panel of the plug-in unit for connecting the optical fiber cable to the optical input connector, and the optical fiber connection work method in this example And explained its effects. The front panel of FIG. 7 is a case where an interface 71 such as a personal computer terminal is mounted in place of the thumb rotary switch so that setting of connection information and reading of setting contents can be performed from the personal computer terminal. In this case, the same effect as that of the thumb rotary switch can be obtained.

The present invention can be applied to various distribution devices such as distribution, redundancy, switching, and relay. Further, the present invention can be applied to various optical signals other than the optical video signal.
In addition to the front panel, the thumb rotary switch or interface may be provided at an appropriate position such as a side surface, a back surface, an upper surface, or a lower surface of the panel.

DESCRIPTION OF SYMBOLS 1 Optical input connector 2 Fiber optical amplifier 3 Optical branch 4 Optical output connector 5 Monitoring control interface part 6 Plug-in connector 7 Thumb rotary switch 8 ACT lamp 9 FAIL lamp 10 Optical input connector 11 Optical switch 12 Optical branch 13 Optical output connector 14 Monitoring Control interface 15 Thumb rotary switch 16 ACT lamp 17 FAIL lamp 18 Plug-in connector 19 Optical input connector 20 Fiber optical amplifier 21 Optical branching 22 Optical output connector 23 Monitoring control interface 26 Plug-in connector 27 ACT lamp 28 FAIL lamp 29 Optical video signal distribution optical amplifier board 30 Optical video signal redundancy switching optical switch branch board 31 Optical video signal relay optical amplifier board 32 Wiring board 33 Monitoring control board 34 Optical fiber cable wiring 35 between plug-in units Recording setting button 36 communication function unit 37 alarm processing, CPU comprising LED lamp controller
38 Memory 301 Monitoring control system 302 Communication control unit 303 Central processing unit 304 Memory 305 Terminal 320 Connection number 321 Connection source type 322 Connection source device number 323 Connection source slot number 324 Connection destination type 325 Connection destination device number 326 Connection destination slot number 327 Device number 328 Slot number 329 Plug-in unit type 330 Service information 41 Wiring board 43 Plug-in connector 44 Basic device 45 Additional device 71 Interface such as personal computer terminal

Claims (9)

A plug-in unit for branching an optical signal input from an optical input connector arranged on the panel surface and outputting it from a plurality of optical output connectors arranged on the panel surface;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
In an optical signal distribution device comprising a monitoring control unit for monitoring and controlling the operating state of the plurality of plug-in units in the cabinet,
The plug-in unit is
Connection destination slot identification information (ID) indicating a slot position where a connection destination plug-in unit which is a connection destination of the other connection end of the optical fiber cable connected to the optical input connector is mounted, and the connection destination plug An interface for setting and displaying a connection destination device ID representing a cabinet accommodating an in-unit by a switch or an external terminal that is manually set and displayed;
A monitoring control interface (IF) that is connected to the switch or the interface and transmits and receives electrical signals to and from the monitoring control unit;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control IF of the connection source plug-in unit transmits the connection destination slot ID and the connection destination device ID converted into electrical signal information by the switch or the interface to the monitoring control unit,
The supervisory control board is an optical signal distribution device that stores the transmitted information transmitted from the supervisory control IF.
The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
With
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, and a connection The optical signal distribution device according to claim 1, wherein the connection type, the connection destination device ID, and the connection destination slot ID of the previous plug-in unit are stored in the connection information table corresponding to the connection number of the connected optical fiber cable. .
One optical signal is selected from the 0-system and 1-system optical signals input from the 0-system and 1-system optical input connectors arranged on the panel surface, and the selected optical signal is branched to be arranged on the panel surface. A plug-in unit that outputs from a plurality of optical output connectors;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
In an optical signal distribution device comprising a monitoring control unit for monitoring and controlling the operating state of the plurality of plug-in units in the cabinet,
The plug-in unit is
0-system connection-destination slot representing a slot position where a 0-system connection-destination plug-in unit that is a connection destination of the other connection end of the 0-system optical fiber cable connected to the 0-system optical input connector is mounted. Identification system (ID) and a 0 system connection destination device ID representing a cabinet that accommodates the connection destination plug-in unit are set and displayed by a 0 system switch or an external terminal that is manually set and displayed. Interface,
A 1-system connection destination that represents a slot position where a 1-system connection-destination plug-in unit that is a connection destination of the other connection end of the 1-system optical fiber cable connected to the 1-system optical input connector is mounted. A 1-system interface for setting and displaying a slot ID and a 1-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by a 1-system switch or an external terminal that is manually set and displayed; ,
A monitoring control interface (IF) connected to the 0 system and 1 system switches or the 0 system and 1 system interfaces and transmitting and receiving electrical signals to and from the monitoring control unit,

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control IF of the plug-in unit of the connection source includes the connection-destination slot IDs of the 0-system and the 1-system converted into electric signal information by the 0-system and 1-system switches or the 0-system and 1-system interfaces. The connection destination device ID is transmitted to the monitoring control unit,
The supervisory control board is an optical signal distribution device that stores the transmitted information transmitted from the supervisory control IF.
The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
With
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, connection source type, connection source device ID and connection slot ID, 0 For the plug-in unit of the connection destination of the system, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, 1 The light according to claim 3, wherein the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable for the plug-in unit of the system connection destination. Signal distribution device.
A plug-in unit for branching an optical signal input from an optical input connector arranged on the panel surface and outputting it from a plurality of optical output connectors arranged on the panel surface;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
A monitoring control unit for monitoring and controlling the operation state of the plurality of plug-in units in the cabinet;
In an optical signal distribution system including a monitoring control system connected to a plurality of the monitoring control units and performing communication constantly or periodically,

The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
A registration setting button for storing connection information in the connection information table of the monitoring control unit and transmitting the connection information to the monitoring control system,

The supervisory control system includes:
The connection information table and the management table of each of the monitoring control units are aggregated and stored in an aggregate connection information table and an aggregation management table, respectively.

The plug-in unit is
A connection destination slot ID indicating a slot position where a connection destination plug-in unit which is a connection destination of the other connection end of the optical fiber cable connected to the optical input connector is mounted, and the connection destination plug-in unit is accommodated An interface for setting and displaying a connection destination device ID representing a cabinet to be set and displayed by a switch or an external terminal that is manually set and displayed;
A supervisory control interface (IF) connected to the switch or the interface and transmitting and receiving electrical signals to and from the supervisory control unit;
An act lamp and a fail lamp controlled by the monitoring control IF;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control IF of the connection source plug-in unit transmits the connection destination slot ID and the connection destination device ID converted into electrical signal information by the switch or the interface to the monitoring control unit,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, and a connection For the previous plug-in unit, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,

The monitoring and control system registers the new or added or changed optical fiber cable connection information as a work table in the same format as the connection information table,
In accordance with the work table, the supervisory control system sequentially instructs the control unit defined by the equipment ID to display the equipment ID, slot ID, and act lamp on the plug-in units of the optical fiber cable connection source and connection destination. To display the act lamp provided in the plug-in unit,
An optical fiber cable is connected between the plug-in units indicated by the act lamp, the optical output connector, and the optical input connector, and the device ID and slot of the connected plug-in unit are connected to the switch or the interface of the connecting plug-in unit. When the ID is set and the registration setting button in the monitoring control unit of the connection source plug-in unit is operated, the connection destination set by the switch or the interface, the type of the connection source plug-in unit, the slot ID, and The device ID is notified from the monitoring control unit to the monitoring control system,
The monitoring control system includes the notified connection destination and connection source plug-in unit type and slot ID and device ID, and the connection destination and connection source plug-in unit type and slot ID registered in the work table. Check the device ID,
If they do not match due to collation, the monitoring control system notifies the device ID and slot ID of the connection source and connection destination plug-in units and the fail lamp display command to the monitoring control unit of the cabinet in which both plug-in units are mounted. Display the fail lamp of the plug-in unit of the connection destination and connection source,
On the other hand, if they match by collation, the monitoring and control system stops the act lamp and the fail lamp in the case of rework, so that the slot ID and device ID of the connection destination and the connection source plug-in unit and the lamp stop command are stopped. To the corresponding monitoring control unit, and the monitoring control system informs the connection destination and the type of the plug-in unit of the connection source, the slot ID, and the device ID, which are the connection information connected this time in the work table. An optical signal distribution system to be added to or updated in the aggregated connection information table.
One optical signal is selected from the 0-system and 1-system optical signals input from the 0-system and 1-system optical input connectors arranged on the panel surface, and the selected optical signal is branched to be arranged on the panel surface. A plug-in unit that outputs from a plurality of optical output connectors;
A cabinet for accommodating the plurality of plug-in units in a plurality of slots,
A monitoring control unit for monitoring and controlling the operation state of the plurality of plug-in units in the cabinet;
In an optical signal distribution system including a monitoring control system connected to a plurality of the monitoring control units and performing communication constantly or periodically,

The monitoring controller is
A management table that stores device identification information (ID) representing a cabinet, a slot ID, and a type of plug-in unit correspondingly;
A connection information table that stores connection information including a connection source device ID, a slot ID, and a type, and a connection destination device ID, a slot ID, and a type for each connection of an optical fiber cable;
A registration setting button for storing connection information in the connection information table of the monitoring control unit and transmitting the connection information to the monitoring control system,

The supervisory control system includes:
The connection information table and the management table of each of the monitoring control units are aggregated and stored in an aggregate connection information table and an aggregation management table, respectively.

The plug-in unit is
0-system connection-destination slot representing a slot position where a 0-system connection-destination plug-in unit that is a connection destination of the other connection end of the 0-system optical fiber cable connected to the 0-system optical input connector is mounted. A 0-system interface for setting and displaying an ID and a 0-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by using a 0-system switch or an external terminal that is manually set and displayed;
A 1-system connection destination that represents a slot position where a 1-system connection-destination plug-in unit that is a connection destination of the other connection end of the 1-system optical fiber cable connected to the 1-system optical input connector is mounted. A 1-system interface for setting and displaying a slot ID and a 1-system connection destination device ID representing a cabinet that accommodates the connection-destination plug-in unit by a 1-system switch or an external terminal that is manually set and displayed; ,
A monitoring control interface (IF) connected to the 0-system and 1-system switches or the 0-system and 1-system interfaces, and for transmitting and receiving electrical signals to and from the monitoring control section;
An act lamp and a fail lamp controlled by the monitoring control IF;

When or after the plug-in unit is installed in the slot, the monitoring control IF sends the predetermined type of the plug-in unit and the predetermined slot ID installed to the monitoring control unit. Communicate
The monitoring control unit stores the device ID representing the cabinet preset in the monitoring control unit, the slot ID transmitted from the monitoring control IF, and the type in the management table,
The monitoring control IF of the plug-in unit of the connection source includes the connection-destination slot IDs of the 0-system and the 1-system converted into electric signal information by the 0-system and 1-system switches or the 0-system and 1-system interfaces. The connection destination device ID is transmitted to the monitoring control unit,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, connection source type, connection source device ID and connection slot ID, 0 For the plug-in unit of the connection destination of the system, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,
The monitoring control unit, based on the information transmitted from the monitoring control IF and the information stored in the management table, for the connection source plug-in unit, a connection source type, a connection source device ID, a connection slot ID, 1 For the plug-in unit of the connection destination of the system, the connection destination type, the connection destination device ID, and the connection destination slot ID are stored in the connection information table corresponding to the connection number of the connected optical fiber cable,

The monitoring and control system registers the new or added or changed optical fiber cable connection information as a work table in the same format as the connection information table,
In accordance with the work table, the supervisory control system sequentially instructs the control unit defined by the equipment ID to display the equipment ID, slot ID, and act lamp on the plug-in units of the optical fiber cable connection source and connection destination. To display the act lamp provided in the plug-in unit,
An optical fiber cable is connected between the plug-in units indicated by the act lamp, the optical output connector, and the optical input connector, and the device ID and slot of the connected plug-in unit are connected to the switch or the interface of the connecting plug-in unit. When the ID is set and the registration setting button in the monitoring control unit of the connection source plug-in unit is operated, the connection destination set by the switch or the interface, the type of the connection source plug-in unit, the slot ID, and The device ID is notified from the monitoring control unit to the monitoring control system,
The monitoring control system includes the notified connection destination and connection source plug-in unit type and slot ID and device ID, and the connection destination and connection source plug-in unit type and slot ID registered in the work table. Check the device ID,
If they do not match due to collation, the monitoring control system notifies the device ID and slot ID of the connection source and connection destination plug-in units and the fail lamp display command to the monitoring control unit of the cabinet in which both plug-in units are mounted. Display the fail lamp of the plug-in unit of the connection destination and connection source,
On the other hand, if they match by collation, the monitoring and control system stops the act lamp and the fail lamp in the case of rework, so that the slot ID and device ID of the connection destination and the connection source plug-in unit and the lamp stop command are stopped. To the corresponding monitoring control unit, and the monitoring control system informs the connection destination and the type of the plug-in unit of the connection source, the slot ID, and the device ID, which are the connection information connected this time in the work table. An optical signal distribution system to be added to or updated in the aggregated connection information table.
The monitoring control system collates the type, slot ID, and device ID of the plug-in unit in the registered work table with the type, slot ID, and device ID stored in the aggregation management table, and both information is different. In this case, the monitoring control unit defined by one or both of the device IDs is notified, and a fail lamp provided in the plug-in unit defined by the slot ID is displayed. Optical signal distribution system.
The monitoring control IF further transmits operation abnormality alarm information including a light input interruption alarm of the plug-in unit to the monitoring control unit by an electrical signal, and the monitoring control unit includes a device ID and a slot in the management table In response to the ID, further memorize the abnormal operation alarm information,
The monitoring control system further stores operation abnormality alarm information of each plug-in unit notified from the monitoring control unit in the aggregation management table in correspondence with a device ID and a slot ID,

In order to display the act lamp of the plug-in unit to be connected, the monitoring control system notifies the monitoring control unit of the slot ID and device ID of the plug-in module of the connection destination and connection source, and then displays the aggregation management table. Refer to the connection source plug-in unit's operation abnormality information to confirm whether there is a light input interruption alarm,
When the supervisory control system confirms that there is a light input interruption alarm, the supervisory control system notifies the supervisory control unit of the corresponding cabinet of a command to display the fail lamp of the plug-in unit of the connection destination and the connection source. The optical signal distribution system according to claim 5, wherein the optical signal distribution system is an optical signal distribution system.
The aggregation management table further includes service information corresponding to the device ID and the slot ID, which is information indicating whether the service is being operated,
Further, when the supervisory control system confirms that there is no light input interruption alarm, the supervisory control system further refers to the aggregation management table to determine whether the connected plug-in unit is in service operation or not. Check
When the monitoring control system confirms that the connection destination plug-in unit is in operation, if there is a display of the connection destination and connection source plug-in unit fail lamps, a command to stop this is displayed. Notify the control unit, wait for the connection information from the monitoring control unit,
On the other hand, if it is confirmed that it is not in operation, the supervisory control system notifies the supervisory control unit of a command to stop the plug-in unit optical output of the connection destination, and the supervisory control system further performs the aggregation management. 9. The optical fiber cable is confirmed to be connected correctly by checking the presence or absence of a light input interruption alarm of the connection source plug-in unit by looking at the table. An optical signal distribution system according to claim 1.

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