JP2010200149A - Communication system, and remote monitoring and control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To construct a remote monitoring and control channel without decreasing the number of user data channels in a system for remotely monitoring and controlling user's equipment from a station device over the Ethernet. <P>SOLUTION: Both a maintenance management (OAM) channel and a user data channel are used together. Namely, user terminals 130, 131 connected to a user's equipment 110 are connected with a station device 100 in a point-to-point manner. Route management over the Ethernet is managed by means of a VLAN. As illustrated, the user terminal 130 is accommodated in the station device 100 by means of a VLAN 120 via the user's equipment 110, and the user terminal 131 is accommodated in the station device 100 by means of a VLAN 121 via the user's equipment 110. An Ethernet OAM frame can be transmitted/received using the user data channel. Thus, a remote monitoring and control channel can be constructed without decreasing the number of user data channels. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a communication system and a remote monitoring control method, and in particular, manages a subscriber apparatus from a communication system and a subscriber accommodation apparatus configured by connecting a subscriber apparatus and a subscriber accommodation apparatus via Ethernet (registered trademark). The present invention relates to a remote monitoring control method for performing maintenance and the like. Hereinafter, the notation that Ethernet is a registered trademark is omitted.

  In recent years, Ethernet has rapidly spread not only in a LAN (Local Area Network) area but also in a carrier network such as a wide area Ethernet service. In addition, the OAM (Operation Administration and Maintenance) function has not been defined in the packet communication protocol used in the network such as Ethernet in contrast to the protocol used in the conventional transmission network such as ATM. Quality control has been an issue. In recent years, ITU-T recommendation Y.1731 (non-patented) has been discussed in the ITU-T (International Telecommunication Union Telecommunication Standardization Sector) and IEEE (Institute of Electrical and Electronics Engineers, Inc.) Document 1) and IEEE 802.1ag (Non-Patent Document 2) were defined, and an OAM function for Ethernet was introduced. Also, standardization of the route switching (protection) method G.8031 (Non-patent Document 3) using OAM has been completed.

  Since standardization as described above enables maintenance management related to communication services in the Ethernet network, practical application of the OAM function in a packet communication network including Ethernet has started. Ethernet is usually applied to a LAN owned by an individual or a corporate user, but its operation is also attracting attention in an infrastructure service provided by a carrier by providing a quality management function. The introduction of Ethernet OAM is also being considered for in-home devices installed in user homes.

  Conventionally, a carrier has provided a service for constructing a relay network between user sites using a dedicated line or IP-VPN. In many cases, the user in this case mainly refers to a corporate user such as a company. The reason is that corporate users have multiple sites at different locations for the purpose of disaster avoidance and load balancing of servers, etc. This is because mutual communication between sites has been required.

  In the relay network service, the bandwidth is guaranteed according to the contract with the user in the relay network provided by the carrier. In general, communication between sites that are far from each other spans multiple networks with different managers, such as access network providers that provide infrastructure close to users and carriers that provide core networks. Bandwidth guarantee was difficult. Therefore, encrypted communication using an upper protocol such as IP-VPN is mainly used for communication between sites that are far from each other. In addition, when the sites are relatively close, an L2-VPN service using MPLS (Multi Protocol Label Switching) or the like is also provided.

  With the standardization of Ethernet OAM as described above, communication management at the Layer 2 (hereinafter referred to as L2) level has become possible. Also, access network providers are shifting from costly dedicated line devices to packet communication devices. As a result, it has become easy to establish a connection for consistently managing the access network and the core network, which has been difficult until now. Specifically, a method is being introduced in which a carrier that provides a core network installs a remote device in a user site and manages the entire communication between user sites across access network providers. In this case, the access network provider is in a position to provide a line to the core network provider (carrier). Conventionally, the carrier close to the lower layer (core network) of the transmission network has been in a position to provide resources to the carrier on the access network side. However, as the functions of the packet communication network are expanded, as described above, the business model Is changing.

ITU-T Recommendation Y.1731 IEEE 802.1ag ITU-T Recommendation G.8031 / Y.1342

  Remote monitoring control used for remote monitoring control when a subscriber device (hereinafter simply referred to as a station device) is remotely monitored and controlled from a subscriber accommodation device (hereinafter simply referred to as a station device) via an Ethernet network. The channel needs to be set. Conventionally, this control channel is set separately from the channel through which user data traffic flows. Since user data is transmitted and received through a user data channel set separately from the remote monitoring control channel, it is necessary to accommodate the remote monitoring control channel and the user data channel for the operation of one in-home device, A channel is required.

  Normally, the number of channels that can be accommodated by station devices and in-home devices is limited, so the remote monitoring control technology using the above-described conventional technology reduces the number of user data channels by setting a dedicated channel for remote monitoring control. This causes a problem of letting go. In addition, the remote monitoring and control technology using the above-described conventional technology has a problem that the resource of the packet communication network is excessively consumed when the administrator of the packet communication network is different from the owner of the in-home device and the station device. It will cause it.

  An object of the present invention is to provide a communication system and a remote monitoring control method that can solve the above-mentioned problems of the prior art and can perform remote monitoring control of a home device from a station device without reducing the number of user data channels. It is to provide.

  An object of the present invention is a network configuration method for managing a home device from a station device via the packet communication network when a network configuration in which different packet communication networks of administrators are connected as an intermediary is applied. An object of the present invention is to provide a communication system and a remote monitoring control method capable of reducing the number of connections for controlling a home device.

  In order to achieve the above-mentioned object, the present invention uses a maintenance management (OAM) channel and a user data channel together, thereby enabling transmission and reception of Ethernet OAM frames using the user data channel. In the present invention, remote monitoring control information is installed in an Ethernet OAM frame and transmitted and received using a user data channel, thereby eliminating the need to set a dedicated channel for remote monitoring control without reducing the number of user data channels. Remote monitoring control can be realized.

  However, since the OAM frame is used for in-home device management, it is necessary to always maintain a connection between the in-home device and the station side device for the OAM channel. Therefore, the present invention selects one of a plurality of user channels as a channel for flowing OAM information, and if any communication failure is recognized in the channel allocated to the OAM, other user channels are selected. The channel assignment to the OAM information is changed so that the OAM information flows. As a result, the present invention can suppress an increase in the number of channels required for user service while maintaining a home device control channel using OAM.

  Specifically, according to the present invention, the object is provided in a user home, the home device that is controlled and monitored from the station device, and the station device that remotely monitors and controls the home device, In a remote monitoring control method for monitoring and controlling a home device from a station device in a communication system having means for transmitting and receiving Ethernet frames to and from each other, the station device and the home device are connected to the Ethernet network. , Ethernet OAM (Operation Administration and Maintenance) frame compliant with ITU-T recommendation Y.1731 is provided, and the station device separates the Ethernet frame transmission / reception interface from the user Ethernet frame / Ethernet OAM frame. A multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit The home device includes an Ethernet frame transmission / reception interface and a user Ethernet frame / Ethernet OAM frame demultiplexing / multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit. The device transmits the Ethernet OAM frame on which remote monitoring control information for reading the state of the in-home device is set to the in-home device in the VLAN channel used for transmission / reception of the user Ethernet frame, The in-home device receives the Ethernet OAM frame loaded with the remote monitoring control information on the VLAN channel used for transmitting / receiving the user Ethernet frame, and the remote monitoring control unit performs remote monitoring control processing and also transmits / receives the user Ethernet frame. VLA used for The NAM channel transmits an Ethernet OAM frame carrying remote monitoring control information of a home device to the station device, and the station device carries the remote monitoring control information on a VLAN channel used for transmission / reception of a user Ethernet frame. This is achieved by receiving an Ethernet OAM frame and the remote monitoring control unit performing a remote monitoring control process.

  According to the present invention, it is possible to perform remote monitoring control of a home device from a station device without reducing the number of user data channels, and a network configuration in which packet communication networks of different administrators are connected as an intermediary is applied. Even in this case, the number of connections for controlling the home device can be reduced.

It is a block diagram which shows the structure of the communication system by one Embodiment of this invention. It is a figure which shows the example of the remote monitoring control channel setting in embodiment of this invention. It is a figure which shows the example of a frame structure of the user frame transmitted / received between a station apparatus and a user terminal. It is a figure which shows the frame structural example of the Ethernet OAM frame transmitted / received between a station apparatus and a subscriber | terminal apparatus. It is a block diagram which shows the structure of a station apparatus. It is a figure which shows the structural example of the VLAN table managed by a station apparatus. It is a block diagram which shows the detailed structure of the Ethernet OAM process part of a station apparatus. It is a block diagram which shows the structure of a household device. It is a figure which shows the structural example of the VLAN table managed by a subscriber | terminal apparatus. It is a block diagram which shows the detailed structure of the Ethernet OAM process part of a household device. 6 is a sequence chart illustrating processing for setting a control VLAN in a home device using a CCM frame in the embodiment of the present invention. 6 is a sequence chart illustrating processing for setting a control VLAN in a home device using a VSM / VSR frame in the embodiment of the present invention. 6 is a sequence chart illustrating processing for setting a control VLAN in a home device using an LB frame in the embodiment of the present invention. In the embodiment of the present invention, it is a sequence chart explaining processing which performs remote monitoring control to a home device. It is a figure explaining the example of the state transition regarding the control VLAN of the subscriber | terminal apparatus in the case of setting a control VLAN using a CCM frame. It is a figure explaining the example of the state transition regarding the control VLAN of the subscriber | terminal apparatus in the case of setting a control VLAN using a VSM / VSR frame or an LB frame.

  Embodiments of a communication system and a remote monitoring control method according to the present invention will be described below in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a communication system according to an embodiment of the present invention.

  A communication system according to an embodiment of the present invention includes a station device 100 installed in a station building of a communication carrier, a home device 110 installed in each subscriber's home, and between the station device 100 and the home device 110. The Ethernet access network 10 is connected by transmission lines 152 and 153. The station device 100 can accommodate a plurality of in-home devices 110 via the Ethernet access network 10. A plurality of user terminals 130 and 131 such as a personal computer (PC) can be connected to the in-home device 110. The station apparatus 100 is connected to a higher level network 40 such as a metro network or a core network via a transmission path 151. The station apparatus 100 and the in-home apparatus 110 are managed by the monitoring control system 190. The in-home device 110 is managed by the monitoring control system 190 via the station device 100.

  FIG. 2 is a diagram showing an example of remote monitoring control channel setting in the embodiment of the present invention, and shows features of the present invention.

  User terminals 130 and 131 connected to the in-home device 110 are connected to the station device 100 in a point-to-point manner. The route management in the Ethernet network is managed by VLAN. In the example illustrated in FIG. 2, the user terminal 130 is accommodated in the station device 100 by the VLAN 120 via the home device 110, and the user terminal 131 is accommodated in the station device 100 by the VLAN 121 via the home device 110. This means that user data transmitted / received by the user terminal 130 is transmitted / received using the VLAN 120, and user data transmitted / received by the user terminal 131 is transmitted / received using the VLAN 121.

  The station apparatus 100 and the in-home apparatus 110 have an Ethernet OAM function conforming to ITU-T Y.1731, and can terminate and insert an Ethernet OAM frame. The Ethernet OAM frame can be transmitted / received using the user data channel. That is, the Ethernet OAM frame can be transmitted / received using the VLAN 120 or the VLAN 121. Remote monitoring control information for performing various controls on the in-home device 110 or the user terminals 130 and 131 using the user data channel and acquiring the status (alarm etc.) of the in-home device 110 or the user terminals 130 and 131 By transmitting and receiving an Ethernet OAM frame equipped with “”, it is possible to reduce the number of necessary channels between the station device 100 and the in-home device 110. The example shown in FIG. 2 uses the VLAN 120 as a remote monitoring control 140 and transmits / receives user data and remote monitoring control information, thereby setting the number of channels set between the station device 100 and the home device 110. Reduced.

  FIG. 3 is a diagram illustrating a frame configuration example of a user frame transmitted / received between the station apparatus 100 and the user terminal 130.

  The user frame includes a destination MAC address 310, a transmission source MAC address 311, a VLAN tag 312, a type 313, and a payload 314. The VLAN tag 312 is standardized by IEEE 802.1Q, and includes a TPID 321 indicating a VLAN tag, a CoS 322 indicating a frame priority, a CFI 323, and a VLAN ID 324 used for VLAN identification. A route in the Ethernet network is determined by the VLAN ID 324. Type 313 is a number for identifying a higher layer protocol. For example, 0x0800 for IPv4.

  FIG. 4 is a diagram illustrating a frame configuration example of an Ethernet OAM frame transmitted / received between the station apparatus 100 and the in-home apparatus 110.

  The Ethernet OAM frame includes a destination MAC address 410, a transmission source MAC address 411, a VLAN tag 412, a type 413, and a payload 414. The type 413 of the Ethernet OAM frame is 0x8902. The payload 414 is Ethernet OAM data, and its format is defined by IEEE 802.1ag and ITU-T Y.1731. The Ethernet OAM frame payload 414 includes an MEG level 421, a version 422, an OpCode 423, a flag 424, a TLV offset 425, and OAM data 426. The MEG level 421 indicates the management level of the Ethernet OAM frame. OpCode 423 is an identifier for identifying the function of Ethernet OAM, and is defined by IEEE 802.1ag and ITU-T Y.1731.

  The contents of OpCode 423 and OAM data 426 differ depending on the type of OAM. FIG. 4 shows, as an example, a format of a VSM / VSR (Vender Specific Message / Vender Specific Reply) frame that can be uniquely set by a vendor. The OpCode of VSM is 0x33, and the Opcode of VSR is 0x32. The OAM data 426 includes an OUI 451, a SubOpcode 452, a type 453, a length 454, and a Value 455.

  The remote monitoring control from the station device to the in-home device in the embodiment of the present invention can be performed by mounting the remote monitoring control information in the Ethernet OAM frame shown in FIG. 4 and transmitting / receiving using the user data channel. . For example, when the remote monitoring control information is mounted on the VSM / VSR frame, the remote monitoring control information is mounted on Value 455. When remote monitoring control information is mounted on other Ethernet OAM frames, remote monitoring control using Ethernet OAM is realized by mounting the remote monitoring control information in an area that can be used independently by the user. .

  The user frame illustrated in FIG. 3 and the Ethernet OAM frame illustrated in FIG. 4 flow in the same VLAN. For this reason, the station apparatus 100 and the in-home apparatus 110 need to determine whether the received frame is a user frame or an Ethernet OAM frame. This determination can be made by reading the received frame types 313 and 413. That is, if the type 313, 413 has 0x8902, the device that has received the frame determines that it is an Ethernet OAM frame, processes the Ethernet OAM frame, and if the type is other than 0x8902, it is a user frame. It discriminate | determines and processes a user frame. Details of these processes will be described later with reference to FIGS. 5 and 7.

  FIG. 5 is a block diagram showing the configuration of the station apparatus 100. The station apparatus 100 includes an upper network IF unit 510, a downlink frame buffer 520, a downlink frame discrimination / multiplexing unit 530, an access network IF unit 540, an uplink frame discrimination / multiplexing unit 550, an uplink frame buffer 560, an Ethernet OAM processing unit 570, a VLAN. A table 580 and a remote monitoring control processing unit 590 are configured.

  In the above description, the upper network IF unit 510 is an interface for transmitting and receiving signals to and from the upper network 40, and transmits and receives user frames and Ethernet OAM frames. The downstream frame buffer 520 is a recording unit for temporarily storing data received from the upper network 40. The downlink frame discriminating / multiplexing unit 530 determines whether the downlink frame is a user frame or an Ethernet OAM frame, and if it is a user frame, sends it to the access network IF unit 540, and if it is an Ethernet OAM frame, the Ethernet OAM process To the unit 570. Further, the downstream frame discrimination / multiplexing unit 530 sends the Ethernet OAM frame sent from the Ethernet OAM processing unit 570 to the access network IF unit 540.

  The access network IF unit 540 is an interface for transmitting and receiving signals to and from the Ethernet access network 10 and transmits and receives user frames and Ethernet OAM frames. The uplink frame discriminating / multiplexing unit 550 discriminates whether the uplink frame is a user frame or an Ethernet OAM frame, and if it is a user frame, sends it to the uplink frame buffer 560, and if it is an Ethernet OAM frame, the Ethernet OAM processing unit Send to 570. Further, the upstream frame discriminating / multiplexing unit 550 sends the Ethernet OAM frame sent from the Ethernet OAM processing unit 570 to the upstream frame buffer 560. The upstream frame buffer 560 is storage means for temporarily storing data to be transmitted to the upper network 40.

  The Ethernet OAM processing unit 570 reads the MEG level 421 of the received Ethernet OAM frame, and determines whether the Ethernet OAM frame is transparent or terminated. When the MEG level 421 of the Ethernet OAM frame is higher than the termination MEG level held by the Ethernet OAM processing unit, the Ethernet OAM processing unit 570 performs transparent processing on the Ethernet OAM frame. Here, the transmission processing means that the Ethernet OAM frame sent from the downstream frame discrimination / multiplexing unit 530 is returned to the downstream frame discrimination / multiplexing unit 530 as it is, and the Ethernet OAM sent from the upstream frame discrimination / multiplexing unit 550. This is a process of returning the frame as it is to the upstream frame discrimination / multiplexing unit 550.

  When the MEG level 421 of the Ethernet OAM frame is equal to or lower than the termination MEG level held by the Ethernet OAM processing unit, the Ethernet OAM processing unit 570 terminates the Ethernet OAM frame and performs Ethernet OAM processing. The Ethernet OAM processing unit 570 has a function of generating an Ethernet OAM frame and transmitting it to the downlink frame discrimination / multiplexing unit 530 or the uplink frame discrimination / multiplexing unit 550.

  The VLAN table 580 stores VLAN information accommodated in the station apparatus 100 and VLAN information used for remote monitoring control. Further, when receiving a remote monitoring control instruction for the home device 110 from the monitoring control system 190, the remote monitoring control processing unit 590 performs remote monitoring control of the home device 110.

  FIG. 6 is a diagram illustrating a configuration example of the VLAN table 580 managed by the station apparatus 100.

  In order to accommodate a plurality of in-home devices, the station device 100 manages three pieces of information in the VLAN table 580: a home device number, a VLAN ID accommodated in the home device, and a control VLAN. The control VLAN is a VLAN that transmits and receives a remote monitoring control Ethernet OAM frame. In the example illustrated in FIG. 6, the station device 100 accommodates two devices 110 and 111. The in-home device 110 accommodates VLAN IDs: 120 and 121, and the in-home device 111 accommodates VLAN ID: 135. The control VLAN that controls the in-home device 110 uses VLAN ID: 120, and the control VLAN that controls the in-home device 111 uses VLAN ID: 135.

  When the in-home device 111 accommodates a plurality of VLANs, the remote monitoring control Ethernet OAM frame is set to be transmitted and received by the specific VLAN. This is to improve manageability. When a failure occurs in a VLAN used for remote monitoring control, the remote monitoring control channel can be switched to another VLAN set in advance. In the example of the in-home device number 110 illustrated in FIG. 6, when a failure occurs in the VLAN 120, it can be switched to the VLAN 121.

  FIG. 7 is a block diagram showing a detailed configuration of the Ethernet OAM processing unit 570 of the station apparatus 100. The Ethernet OAM processing unit 570 includes an OpCode determination unit 710, an Ethernet OAM generation unit 720, a CCM processing unit 730, a VSM / VSR processing unit 740, and other Ethernet OAM processing unit 750.

  The OpCode discriminating unit 710 reads the OpCode 423 of the Ethernet OAM frame sent from the uplink frame discriminating / multiplexing unit 550 or the downlink frame discriminating / multiplexing unit 530, determines the transmission destination of the Ethernet OAM frame based on the value of OpCode 423, and sends it out. . For example, the OpCode determination unit 710 sends the received Ethernet OAM frame to the CCM processing unit 730 if the OpCode is 0x01 CCM.

  The CCM processing unit 730 monitors the connectivity of the VLAN channel by CCM reception. In other words, the CCM processing unit 730 confirms the connectivity of the VLAN by reading the VLAN tag of the CCM. The CCM processing unit 730 determines that a channel failure has occurred if CCM non-reception continues for a certain period of time, and instructs the Ethernet OAM generation unit 720 to generate and transmit an AIS (Alarm Indication Signal) and an RDI (Remote Defect Indication). To do.

  The VSM / VSR processing unit 740 performs VSM / VSR termination processing of the Ethernet OAM frame transmitted by the OpCode determination unit 710 determining the OpCode 423 of the Ethernet OAM frame. That is, when receiving the remote monitoring control VSR, the VSM / VSR processing unit 740 sends the remote monitoring control information to the remote monitoring control processing unit 590. When the VSM / VSR processing unit 740 receives an instruction from the remote monitoring control processing unit 590 to transmit the remote monitoring control VSM to the home device 110, the VSM / VSR processing unit 740 generates the remote monitoring control VSM to the Ethernet OAM generating unit 720. Instructs device 110 to send a remote monitoring control VSM.

  The other Ethernet OAM processing unit 740 performs termination processing of Ethernet OAMs (for example, AIS) other than the CCM, VSM, and VSR transmitted by the OpCode determination unit 710 determining the OpCode 423 of the Ethernet OAM frame. Further, the other Ethernet OAM processing unit 740 instructs the Ethernet OAM generation unit 720 to generate / send the Ethernet OAM.

  The Ethernet OAM generation unit 720 receives an instruction from the CCM processing unit 730, the VSM / VSR processing unit 740, or the other Ethernet OAM processing unit 750, generates an Ethernet OAM frame, and performs an uplink frame discrimination / multiplexing unit 550 or a downlink frame discrimination / multiplexing. To the unit 530.

  FIG. 8 is a block diagram showing the configuration of the home device 110. The in-home device 110 includes an access network IF unit 810, a downlink frame discrimination / multiplexing unit 820, a downlink frame buffer 830, a subscriber network IF unit 840, an uplink frame buffer 850, an uplink frame discrimination / multiplexing unit 860, an Ethernet OAM processing unit 870, A VLAN table 880 and a remote monitoring control processing unit 890 are configured.

  In the above description, the access network IF unit 810 is an interface for transmitting and receiving signals to and from the Ethernet access network 10, and transmits and receives user frames and Ethernet OAM frames. The downlink frame discriminating / multiplexing unit 820 discriminates whether the downlink frame is a user frame or an Ethernet OAM frame, and if it is a user frame, sends the frame to the downlink frame buffer 830. If so, the frame is sent to the Ethernet OAM processing unit 870. Further, the downlink frame discriminating / multiplexing unit 820 sends the Ethernet OAM frame sent from the Ethernet OAM processing unit 870 to the downlink frame buffer 830. The downlink frame buffer 830 is a storage unit for temporarily storing data to be transmitted to the subscriber network.

  The subscriber network IF unit 840 is an interface for transmitting and receiving signals to and from the user terminal 130 owned by the subscriber, and transmits and receives user frames and Ethernet OAM frames. The upstream frame buffer 850 is a storage means for temporarily storing data received from the subscriber network. The uplink frame discriminating / multiplexing unit 860 discriminates whether the uplink frame is a user frame or an Ethernet OAM frame, and if it is a user frame, sends the frame to the access network IF unit 810 and uses the Ethernet OAM frame. If there is, the frame is sent to the Ethernet OAM processing unit 870. Further, the upstream frame discrimination / multiplexing unit 860 sends the Ethernet OAM frame sent from the Ethernet OAM processing unit 870 to the access network IF unit 810.

  The Ethernet OAM processing unit 870 reads the MEG level 421 of the received Ethernet OAM frame and determines whether the Ethernet OAM frame is transparent or terminated. If the MEG level 421 of the Ethernet OAM frame is higher than the termination MEG level held by the Ethernet OAM processing unit, the Ethernet OAM processing unit 870 performs transparent processing on the Ethernet OAM frame. Here, the transmission processing means that the Ethernet OAM frame sent from the downstream frame discrimination / multiplexing unit 820 is returned to the downstream frame discrimination / multiplexing unit 820 as it is, and the Ethernet OAM sent from the upstream frame discrimination / multiplexing unit 860 is used. This is a process of returning the frame as it is to the upstream frame discrimination / multiplexing unit 860. The Ethernet OAM processing unit 870 terminates the Ethernet OAM frame and performs Ethernet OAM processing when the MEG level 421 of the Ethernet OAM processing unit is equal to or lower than the termination MEG level held by the Ethernet OAM processing unit based on the above-described determination. . Further, the Ethernet OAM processing unit 870 has a function of generating an Ethernet OAM frame and transmitting it to the downlink frame discrimination / multiplexing unit 820 or the uplink frame discrimination / multiplexing unit 860.

  The VLAN table 880 is a table that stores VLAN information accommodated in the in-home device 110 and VLAN information used for remote monitoring control. The remote monitoring control processing unit 890 performs remote monitoring control processing for the user terminal.

  FIG. 9 is a diagram showing a configuration example of the VLAN table 880 managed by the home device 110.

  The in-home device that can accommodate a plurality of VLANs determines which VLAN is used to transmit / receive the remote monitoring control VSM / VSR based on the VLAN table 880. In the example of the figure, the in-home device accommodates VLAN IDs: 120 and 121, and it is described that the VLAN ID: 120 is used as the control VLAN. Control frames received with a VLAN ID other than 120 are discarded. This is to prevent erroneous inflow of the control frame due to erroneous connection.

  When the in-home device 111 accommodates a plurality of VLANs, the remote monitoring control Ethernet OAM frame is set to be transmitted and received by the specific VLAN. In addition, when a failure occurs in the VLAN used for remote monitoring control, the remote monitoring control channel is switched to another preset VLAN.

  FIG. 10 is a block diagram showing a detailed configuration of the Ethernet OAM processing unit 870 of the in-home device 110. The Ethernet OAM processing unit 870 includes an OpCode determination unit 1010, an Ethernet OAM generation unit 1020, a CCM processing unit 1030, a VSM / VSR processing unit 1040, and other Ethernet OAM processing unit 1050.

  The OpCode discriminating unit 1010 reads the OpCode 423 of the Ethernet OAM frame sent from the uplink frame discriminating / multiplexing unit 860 or the downlink frame discriminating / multiplexing unit 820, determines the destination of the Ethernet OAM frame based on the value of the OpCode 423, and sends it out. . For example, the OpCode determination unit 1010 transmits the received Ethernet OAM frame to the CCM processing unit 1030 if the OpCode is 0x01 CCM.

  The CCM processing unit 1030 monitors the connectivity of the VLAN channel by CCM reception. That is, the CCM processing unit 1030 confirms the connectivity of the VLAN by reading the VLAN tag of the CCM. The CCM processing unit 1030 determines that a channel failure has occurred when CCM non-reception continues for a certain period of time, and instructs the Ethernet OAM generation unit 1020 to generate and send AIS and RDI.

  The VSM / VSR processing unit 1040 performs VSM / VSR termination processing of the Ethernet OAM frame transmitted by the OpCode determination unit 1010 determining the OpCode 423 of the Ethernet OAM frame. That is, when receiving the remote monitoring control VSM, the VSM / VSR processing unit 1040 sends the remote monitoring control information to the remote monitoring control processing unit 890. When the VSM / VSR processing unit 1040 receives an instruction from the remote monitoring control processing unit 890 to transmit the remote monitoring control VSR to the station device 100, the VSM / VSR processing unit 1040 generates the remote monitoring control VSR to the Ethernet OAM generating unit 1020 and Instructs the device 100 to transmit the remote monitoring control VSR.

  The other Ethernet OAM processing unit 1050 performs termination processing of an Ethernet OAM (for example, AIS) other than the CCM, VSM, and VSR transmitted by the OpCode determination unit 710 determining the OpCode 423 of the Ethernet OAM frame. The other Ethernet OAM processing unit 1050 instructs the Ethernet OAM generation unit 1020 to generate and send the Ethernet OAM.

  The Ethernet OAM generation unit 1020 receives an instruction from the CCM processing unit 1030, the VSM / VSR processing unit 1040, or the other Ethernet OAM processing unit 1050, generates an Ethernet OAM frame, and performs an uplink frame discrimination / multiplexing unit 860 or a downlink frame discrimination / multiplexing To the unit 820.

  FIG. 11 is a sequence chart for explaining processing for setting a control VLAN in the in-home device 110 using a CCM frame in the embodiment of the present invention. Next, this will be explained. In the example of the sequence described here, the control VLAN is registered from the station device 100 to the in-home device 110 in order to register the set value in the in-home device 110 in a state where the control VLAN is not set in the in-home device 110 at the time of activation. It is an example of a process in the case of setting remotely.

(1) First, the monitoring control system 190 notifies the station device 100 of the ID of the in-home device 110 to be set and the VLAN ID through which the remote monitoring control signal is sent (sequence 1101).

(2) The station device 100 writes the ID and VLAN ID of the in-home device notified from the monitoring control system 190 into the VLAN table 580 in the own device, and stores the CCM frame with the tag of the notified VLAN ID in the home The data is sent to the device 110 (sequence 1102 and 1103).

(3) The in-home device 110 holds the VLAN ID of the CCM frame received from the station device 100. Then, for example, when the in-home device 110 receives CCM frames having the same VLAN ID N times consecutively (for example, N = 5), the home device 110 sets the VLAN as a control VLAN (sequence 1104).

(4) At the same time, the in-home device 110 writes the control VLAN in the VLAN table 880 in its own device, and assigns the VLAN ID set to the control VLAN to notify the station device 100 that the setting has been completed. The CCM frame is transmitted to the station apparatus 100 (sequences 1105 and 1106).

(5) When the station device 100 receives the CCM frame with the control VLAN tag from the home device 110 N times (for example, N = 5), the station device 100 confirms that the setting of the control VLAN is normally completed. The setting completion notification is sent to the monitoring control system (sequences 1107 and 1108).

(6) Upon receiving the setting completion notification from the station apparatus 100, the monitoring control system 190 confirms that the setting of the control VLAN has been completed normally (sequence 1109).

  FIG. 12 is a sequence chart for explaining processing for setting a control VLAN in the in-home device 110 using the VSM / VSR frame in the embodiment of the present invention. Next, this will be explained.

(1) First, the monitoring control system 190 notifies the station device 100 of the ID of the in-home device 110 to be set and the VLAN ID through which the remote monitoring control signal is sent (sequence 1201).

(2) The station device 100 writes the ID and VLAN ID of the in-home device notified from the supervisory control system 190 into the VLAN table 580 in the own device, and stores the VSM frame to which the tag of the notified VLAN ID is added. The data is sent to the apparatus 110 (sequence 1202, 1203).

(3) The in-home device 110 sets the VLAN ID of the VSM frame received from the station device 100 to the control VLAN. At the same time, the in-home device 110 writes the control VLAN in the VLAN table 880 in the own device, and adds a tag of the VLAN ID set in the control VLAN to notify the station device 100 that the setting is completed. The transmitted VSR frame is sent to the station apparatus 100 (sequence 1204 to 1206).

(4) The station apparatus 100 receives the VSR frame to which the control VLAN tag is attached, thereby confirming that the setting of the control VLAN has been normally completed, and sends a setting completion notification to the monitoring control system 190 ( Sequence 1207, 1208).

(5) Upon receiving the setting completion notification from the station apparatus 100, the supervisory control system 190 confirms that the setting of the control VLAN has been completed normally (sequence 1109).

  FIG. 13 is a sequence chart for explaining processing for setting a control VLAN in the in-home device 110 using the LB frame in the embodiment of the present invention. Next, this will be explained.

(1) First, the monitoring control system 190 notifies the station device 100 of the ID of the in-home device 110 to be set and the VLAN ID through which the remote monitoring control signal is sent (sequence 1301).

(2) The station device 100 writes the ID and VLAN ID of the in-home device notified from the monitoring control system 190 in the VLAN table 580 in its own device, and stores the LB frame with the tag of the notified VLAN ID in the home The data is sent to the apparatus 110 (sequences 1302 and 1303).

(3) The in-home device 110 holds the VLAN ID of the LB frame received from the station device 100. Then, for example, when the premises frame 110 receives LB frames with the same VLAN ID N times (for example, N = 5) continuously, the premises device 110 sets the VLAN as a control VLAN (sequence 1304).

(4) At the same time, the in-home device 110 writes the control VLAN in the VLAN table 880 in its own device, and assigns the VLAN ID set to the control VLAN to notify the station device 100 that the setting has been completed. The LB frame is transmitted to the station apparatus 100 (sequences 1305 and 1306).

(5) The station device 100 receives the LB frame with the control VLAN tag from the in-home device 110, thereby confirming that the setting of the control VLAN is normally completed, and sends a setting completion notification to the monitoring control system. (Sequence 1307, 1308).

(6) Upon receiving the setting completion notification from the station apparatus 100, the monitoring control system 190 confirms that the setting of the control VLAN has been completed normally (sequence 1309).

  FIG. 14 is a sequence chart for explaining processing for performing remote monitoring control on the in-home device 110 in the embodiment of the present invention. Next, this will be explained.

(1) When performing remote monitoring control of the home device 110, first, the monitoring control system 190 transmits the remote monitoring control information of the home device 110 to the station device 100 (sequence 1401).

(2) Upon receiving the remote monitoring control information from the in-home device 110, the station device 100 causes the remote monitoring control processing unit 590 in the own device to decode the received remote monitoring control information, and the remote monitoring control processing unit 590 According to the result of decoding, an instruction to generate a remote monitoring control VSM frame is issued to the Ethernet OAM processing unit 570 (sequence 1402).

(3) The Ethernet OAM processing unit 570 reads the control VLAN from the VLAN table 580, generates a remote monitoring control VSM frame using the control VLAN, and transmits the generated remote monitoring control VSM frame to the in-home device 110. (Sequence 1403).

(4) The in-home device 110 reads the remote monitoring control information from the received remote monitoring control VSM frame, and reflects the received remote monitoring control information in the remote monitoring control processing unit 890 in the own device (sequence 1404).

(5) The in-home device 110 instructs the remote monitoring control processing unit 890 to generate the remote monitoring control response VSR frame to the Ethernet OAM processing unit 870 in order to notify the setting completion, and the remote monitoring control response VSR frame And the generated remote monitoring control response VSR frame is transmitted to the station apparatus 100. The response frame is transmitted using the control VLAN (sequences 1405 and 1406).

(6) Upon receiving the response frame, the station device 100 confirms that the setting by the remote monitoring control is completed by the response frame received by the remote monitoring control processing unit 590, and sends a setting completion notification to the monitoring control system 190. (Sequence 1407, 1408).

(7) Upon receiving the setting completion notification from the station apparatus 100, the monitoring control system 190 confirms that the setting by the remote monitoring control has been completed normally (sequence 1409).

  FIG. 15 is a diagram for explaining an example of state transition related to the control VLAN of the in-home device 110 when the control VLAN is set using the CCM frame in the embodiment of the present invention. Next, this will be described.

(1) The initial state of the home device 110 is a control VLAN non-setting state 1510. The household device 110 shifts to the protection state 1520 by receiving the CCM in this state (transition 1551).

(2) The in-home device 110 transitions to the control VLAN setting state 1530 by receiving the same CCM continuously N times (for example, N = 5) in the protection state 1520, and the control VLAN is set (transition) 1552). Further, even if the CCM is received, if the same CCM continuous reception is less than N times, the protected state 1520 remains (transition 1556).

(3) In addition, the in-home device 110 performs CCM N times (for example, N = 3) in the protection state 1520.
If not received, it is recognized that LOC (Loss Of Continuity) has occurred, and the state shifts to the control VLAN non-setting state 1510 (transition 1554).

(4) If the home device 110 does not receive the control VLAN CCM N times (for example, N = 3) in the control VLAN setting state 1530, it recognizes the occurrence of LOC (Loss Of Continuity) and performs control. The state shifts to the non-setting VLAN state 1510 and the control VLAN is not set (transition 1555).

(5) Further, in the control VLAN setting state 1530, the in-home device 110 transitions to the protection state 1520 when a CCM of a VLAN other than the control VLAN is received (transition 1553).

(6) Further, when the in-home device 110 receives the CCM N times (for example, N = 5) continuously in the protection state 1520, the control VLAN is reset to a new VLAN and the control VLAN setting state 1530 (Transition 1552).

  FIG. 16 is a diagram illustrating an example of state transition related to the control VLAN of the home device 110 when the control VLAN is set using the VSM / VSR frame or the LB frame in the embodiment of the present invention. This will be described.

(1) The initial state of the home device 110 is a control VLAN non-setting state 1610. The in-home device 110 shifts to the control VLAN setting state 1620 by receiving the VSM frame or the LB frame in this state (transition 1651).

(2) In the control VLAN setting state 1620, the in-home device 110 transmits / receives a CCM frame to / from the station device 100 using the control VLAN, and monitors connectivity.

(3) If the home device 110 does not receive the control VLAN CCM N times (for example, N = 3) in the control VLAN setting state 1620, it recognizes that LOC (Loss Of Continuity) has occurred and The process shifts to the VLAN non-set state 1610, and the control VLAN is not set (transition 1652).

  According to the above-described embodiment of the present invention, remote monitoring control between the station device 100 and the in-home device 110 is mounted on the user data channel without using a dedicated channel for remote monitoring control. It can be executed by transmitting and receiving Ethernet OAM frames. As a result, according to the embodiment of the present invention, it is possible to construct a remote monitoring control channel that can perform remote monitoring control of a home device from a station device without reducing the number of user data channels.

  Further, according to the above-described embodiment of the present invention, in the channel setting in the packet relay network, only the channel used for user data is necessary, and the finite number of interfaces on the device side can be saved. It is possible to reduce the consumption of resources (such as the number of VLAN labels) in the packet relay network and to efficiently use the bandwidth of the packet communication network.

  Further, according to the above-described embodiment of the present invention, in OAM channel switching, since a channel set in advance between the station device and the in-home device is reassigned, other channels in the packet communication network are switched at the time of channel switching. The influence on the setting of the traffic and the packet communication network can be avoided.

  Furthermore, according to the above-described embodiment of the present invention, monitoring all channels set for user data leads to a decrease in communication efficiency in consideration of bandwidth consumption by OAM frames. And the switching of the OAM channel so that only highly important OAM information can always be communicated can be avoided. This point is particularly effective for connection management via a best-effort packet communication network.

10 Ethernet access network 40 Host network 100 Station device 110 Home device 120, 121 VLAN
130, 131 User terminal 140 Control VLAN
151, 152, 153 Transmission path 190 Monitoring control system 510 Upper network IF unit 520, 830 Downstream frame buffer 530, 820 Downstream frame discrimination / multiplexing unit 540, 810 Access network IF unit 550, 860 Upstream frame discrimination / multiplexing unit 560, 850 Upstream frame buffer 570, 870 Ethernet OAM processing unit 580, 880 VLAN table 590 Remote monitoring control processing unit 710, 1010 OpCode determination unit 720, 1020 Ethernet OAM generation unit 730, 1030 CCM processing unit 740, 1040 VSM / VSR processing unit 750, 1050 Other Ethernet OAM processing unit 840 Subscriber network IF unit 890 Remote monitoring control processing unit

Claims (7)

A home device installed in the user's home and controlled and monitored from the station device and a station device for remotely monitoring and controlling the home device are provided, and the station device and the home device are connected to an Ethernet network, In a communication system comprising means for transmitting and receiving Ethernet frames,
The station device and the in-home device have a function of terminating and inserting an Ethernet OAM (Operation Administration and Maintenance) frame compliant with ITU-T recommendation Y.1731.
The station apparatus includes an Ethernet frame transmission / reception interface and a user Ethernet frame / Ethernet OAM frame separation / multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit,
The in-home device includes an Ethernet frame transmission / reception interface and a user Ethernet frame / Ethernet OAM frame separation / multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit,
The station device sets the in-home device using a VLAN channel used for transmitting / receiving a user Ethernet frame, and transmits an Ethernet OAM frame carrying remote monitoring control information for reading the state of the in-home device to the in-home device. ,
The in-home device receives an Ethernet OAM frame loaded with the remote monitoring control information on a VLAN channel used for transmission / reception of a user Ethernet frame, and the remote monitoring control unit performs a remote monitoring control process, and Sends an Ethernet OAM frame loaded with remote monitoring control information of a home device to the station device using a VLAN channel used for transmission and reception;
The station apparatus receives a Ethernet OAM frame carrying the remote monitoring control information on a VLAN channel used for transmission / reception of a user Ethernet frame, and the remote monitoring control unit performs a remote monitoring control process. system. A home device installed in the user's home and controlled and monitored from the station device and a station device for remotely monitoring and controlling the home device are provided, and the station device and the home device are connected to an Ethernet network, In a remote monitoring control method for monitoring and controlling a home device from a station device in a communication system provided with means for transmitting and receiving an Ethernet frame,
The station device and the in-home device have a function of terminating and inserting an Ethernet OAM (Operation Administration and Maintenance) frame compliant with ITU-T recommendation Y.1731.
The station apparatus includes an Ethernet frame transmission / reception interface and a user Ethernet frame / Ethernet OAM frame separation / multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit,
The in-home device includes an Ethernet frame transmission / reception interface and a user Ethernet frame / Ethernet OAM frame separation / multiplexing unit, an Ethernet OAM frame generation / termination processing unit, and a remote monitoring control processing unit,
The station device sets the in-home device using a VLAN channel used for transmitting / receiving a user Ethernet frame, and transmits an Ethernet OAM frame carrying remote monitoring control information for reading the state of the in-home device to the in-home device. ,
The in-home device receives an Ethernet OAM frame loaded with the remote monitoring control information on a VLAN channel used for transmission / reception of a user Ethernet frame, and the remote monitoring control unit performs a remote monitoring control process, and Sends an Ethernet OAM frame loaded with remote monitoring control information of a home device to the station device using a VLAN channel used for transmission and reception;
The station apparatus receives an Ethernet OAM frame carrying the remote monitoring control information on a VLAN channel used for transmission / reception of a user Ethernet frame, and the remote monitoring control unit performs a remote monitoring control process. Monitoring control method. The remote monitoring control method according to claim 2, wherein
The station apparatus has means for storing a VLAN channel used for remote monitoring control, and transmits / receives an Ethernet OAM frame carrying remote monitoring control information using the VLAN channel. Control method. The remote monitoring control method according to claim 2, wherein
The station apparatus transmits an Ethernet OAM frame to a VLAN channel used for remote monitoring control,
Upon receiving the Ethernet OAM frame, the in-home device stores the VLAN channel as a VLAN channel used for remote monitoring control, and transmits / receives an Ethernet OAM frame carrying remote monitoring control information using the VLAN channel. A remote monitoring control method characterized by: The remote monitoring control method according to claim 4, wherein
A remote monitoring control method characterized in that a VLAN channel used for remote monitoring control is notified from the station device to the home device by periodically transmitting an Ethernet OAM CCM frame from the station device to the home device. . The remote monitoring control method according to claim 4, wherein
A remote monitoring control method, wherein a VLAN channel used for remote monitoring control is notified from the station device to the home device by transmitting an Ethernet OAM VSM frame from the station device to the home device. The remote monitoring control method according to claim 4, wherein
A remote monitoring control method, wherein a VLAN channel used for remote monitoring control is notified from the station device to the home device by transmitting an Ethernet OAM LB frame from the station device to the home device.

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