JP4235572B2 - Transmission equipment - Google Patents

Description

  The present invention relates to a transmission apparatus, and more particularly to a transmission apparatus that transmits a fixed band signal by circuit emulation using a packet transmission network. The packet is particularly related to a MAC frame and an IP frame defined by IEEE 802.3, but is not limited thereto.

  As the first prior art in the present invention, ITU-T Recommendation G. SDH transmission method (Non-patent Document 1) defined in 707, There is a PDH transmission method (Non-Patent Document 2) defined in 703. This Recommendation G. According to 707, a mapping method for a fixed band channel having a band that is an integral multiple of 64 kbit / s is defined in a frame structure that is defined in units of 125 μsec. Various OAM (Operation Administration Maintenance) information is defined as a fixed-band time slot called overhead. On the other hand, in the PDH system, the frame period and the mapping method are not necessarily in units of 125 μsec, but the fixed bandwidth channel and the time slot for mapping the OAM information are fixedly defined. .

  In addition, as a second prior art, the recommendation I.I. 363.1 (Non Patent Literature 3) exists. According to this recommendation, a method for mapping a fixed-band signal to a fixed-length packet called a 53-byte ATM cell is defined as AAL1. As a specific mapping method, in order to detect erroneous delivery due to cell transmission loss or cell header error, the sequence number is transmitted with CRC protection information using 1 byte in the 48-byte payload. The remaining 47-byte area is an information channel mapping area. For OAM information, the recommendation I.I. As defined in 610, a dedicated cell for OAM information transfer called an OAM cell is defined for each layer such as VP or VC, and the signal channel and the OAM information are transferred in different packets.

Furthermore, as a third conventional technology, it was published as PWE3 (Pseudo Wire Emulation) in the Internet draft draft-ietf-pwe3-sonet-01, using the method discussed in the IETF (Internet Engineering Task Force). There is a method. In this method, overhead including a sequence number and a pointer is added to the payload of an IP frame, and an information channel is stored in a plurality of layers of protocol frames such as RTP for transmission.
ITU-T G. 707 / Y. 1322 (12/2003), SERIES G: TRANSMISSION SYSTEMS AND MEDIA, DIGITAL SYSTEMS AND NETWORKS, Digital terminal equipment for H & D. ITU-T G. 703 (11/2001), SERIES G: TRANSMISSION SYSTEMS AND MEDIA, DIGITAL SYSTEMS AND NETWORKS, Digital terminal equipment, general / electrical characteristics. ITU-T I.I. 363.1 (08/96), SERIES I: INTEGRATED SERVICES DIGITAL NETWORKS, Overall networks aspects and functions-Protocol layer requirements, B-ISDN ATM Adaptation Layer specification: Type 1 AAL

  In recent years, with the development of data communication mediated by the Internet, a situation in which data traffic exceeds voice traffic has occurred. Data communication using IP frames and IEEE802.3-compliant MAC frames is widely applied not only to in-house communication but also to subscriber systems and relay systems, and is becoming a standard. In data communication using IP frames or IEEE802.3 compliant MAC frames, real-time performance such as voice is rarely required, and even if packet loss due to bit errors during communication occurs, terminal-terminal Data loss can be compensated by retransmitting packets between the two. For this reason, construction of IP-VPN networks and wide-area Ethernet networks employing devices such as low-cost switches, hubs, media converters, etc. with a simple configuration as relay transmission devices is proceeding at a rapid pace. Furthermore, as the data traffic increases in the future, the spread of these will further advance and further cost reduction is expected.

  On the other hand, the conventional voice, leased line, and ATM transmission devices are required to have a low delay and highly reliable device configuration, and the number of produced units is limited. Since these conventional networks are networks in which network resources are fixedly allocated corresponding to the peak bandwidth, it is inevitable that the cost and thus the communication fee borne by the user increase as the bandwidth increases. On the other hand, although data traffic requires high speed for a short time, most of the time has an average bandwidth of medium speed, so the packet data network suppresses the increase in network resources by sharing the bandwidth between users. . Therefore, even if accepting an increase in delay amount and a decrease in reliability that do not affect the host application, there is an increasing demand for users seeking a low-cost network. In addition, as a carrier, the focus of investment is shifting to IP-VPN networks and wide-area Ethernet networks, which are expected to grow in the future, and additional investments in conventional voice, leased line, and ATM transmission networks are in the direction of restraint. However, since it is necessary to continue providing services for end users corresponding to conventional voice, leased line, and ATM, for the time being, both the conventional network and the data network must be owned. In order to reduce this cost burden, there is a means for sequentially discarding the existing conventional network by accommodating the conventional voice, dedicated line, and ATM service in the data network such as the IP-VPN network and the wide area Ethernet network. It is thought that it will be requested in the future.

  By the way, if the payload length of the packet is not sufficiently long compared to the header length, the transfer efficiency due to packetization is significantly lowered, which is not desirable. However, if a low-speed service such as voice or primary rate service (1.5 Mbit / s) is delayed until a sufficiently long packet payload is filled, the low delay that is a requirement of the fixed bandwidth service cannot be satisfied. In order to eliminate this restriction, it is possible to achieve both high efficiency and low delay by multiplexing information of a plurality of channels and mapping it to one packet.

  A first problem to be solved by the present invention is to provide means for accommodating conventional voice, dedicated line, and ATM services in a data network such as an IP-VPN network or a wide area Ethernet network. In order to accommodate these conventional services, it is necessary not only to transfer user channel information but also to have a function to transfer OAM information provided in conventional networks such as alarm transfer, network clock, and performance monitoring.

  The second problem to be solved by the present invention is that the same route is transferred halfway, but the user channel information with different final destinations is multiplexed to the same packet halfway, and the channels are rearranged in the data network. It is to provide a means to transfer to the final destination.

  In order to solve the above problems, the network of the present invention includes a transmission device that converts a fixed-band signal into a packet signal, a multiplexing device that multiplexes signals of a plurality of user channels into the same packet, and multiplexing within the same packet. A cross-connect device that rearranges a plurality of user channels and transfers them to another route.

  When converting a fixed band signal into a packet signal, an additional information bit is added to transfer OAM information in addition to a packet header in which routing information is stored. In addition, in order to multiplex user channel information with different final destinations into the same packet partway, a multiplexing section layer is defined below the layer stretched end-to-end before multiplexing. The packet header and additional information bits are added for each user channel in the two-end layer and for each section connection in the multiplexed section layer. As additional information, alarm transfer information, performance information, timing information / pointer, sequence number, signal type label, and the like are given as necessary.

According to the first solution of the present invention,
A transmission device for converting a fixed band signal into a packet signal and vice versa, and for embedding maintenance management information that communicates the communication state of the transmission section with each other as additional information inside the packet format data,
A first fixed band signal terminator that terminates the fixed band signal and separates into main signal information and maintenance management information;
A first information storage buffer for receiving and storing main signal information from the output of the first fixed band signal termination unit;
A first synchronous read control unit for controlling reading of main signal information of a fixed band signal from the first information storage buffer;
A maintenance management information detection unit for detecting maintenance management information from the output of the first fixed band signal termination unit;
Communication related to an alarm for transmitting a warning in a physical layer in a time division multiplexing line or an error for transmitting a line quality based on information output from the maintenance management information detection unit and the first synchronous read control unit An additional information assembling unit that generates additional information to be added to the packet signal, including state display information and a pointer indicating a head position of the fixed band signal;
A predetermined length of data obtained by multiplexing or separating the fixed band signal output from the first information storage buffer and additional information output from the additional information assembly unit are included in the payload, and a header including routing information is added. A frame assembly unit for assembling a frame and outputting it as a packet signal;
A frame termination for terminating the packet signal;
An additional information separation unit that terminates additional information of the packet signal received by the frame termination unit;
A second information storage buffer for receiving and storing main signal information of the packet signal received by the frame termination unit;
A second synchronous read control unit for controlling reading of a fixed band signal from the second information storage buffer;
Based on the information received from the maintenance management information detection unit and the additional information separation unit, a maintenance management information giving unit that assembles maintenance management information;
A second fixed band signal terminating unit that assembles and transmits a fixed band signal based on main signal information read from the second information storage buffer and maintenance management information received from the maintenance management information giving unit;
The transmission apparatus is provided.

  The present invention makes it possible to accommodate a conventional voice, dedicated line, and ATM service in a data network such as an IP-VPN network or a wide area Ethernet network, thereby reducing the cost burden of having both the conventional network and the data network. Can be reduced.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a network configuration according to the present embodiment. This network is a conventional STM network (Synchronous Transfer Module) 101-1, 2, Ethernet (registered trademark) work network or IP packet network 102, and converts a fixed band signal related to the present embodiment into a packet signal or vice versa. STM-IP converters 103-1 and 2 that perform conversion, terminals 104-1 to 104-4 connected to the STM network, and terminals 105-1 and 105-2 connected to an Ethernet (registered trademark) work network or an IP packet network .

  The terminal device 104-1 is directly accommodated in the STM-IP conversion device 103-1, via the STM network 101-1, and the terminal device 104-2. The STM-IP conversion apparatus 103-1 accommodates the STM network 101-1, converts it into an Ethernet frame or an IP packet, and sends a signal to the Ethernet (registered trademark) work network or the IP packet network 102. The Ethernet (registered trademark) work network or IP packet network 102 is connected to the STM-IP conversion apparatuses 103-1 and 103-2 and the terminals 105-1 and 105-2 connected to the Ethernet (registered trademark) work network or IP packet network. Then, the Ethernet frame or IP packet input from each device is routed. The STM-IP conversion apparatus 103-2 reconfigures the signal received from the Ethernet (registered trademark) work network or the IP packet network 102 into an STM frame, and is connected to the STM via the STM network 101-2. 2 or a signal is sent to the terminal 104-3 directly connected to the STM.

  In the above description, the signal flow from the terminals 104-1 to 104-4 connected to the STM network has been described. However, the signal flow from the terminals 104-4 to 104-1 connected to the STM is also described. Similar protocol conversion is performed, and bidirectional signal transmission / reception is possible.

  FIG. 2 is a block diagram showing a network configuration in the Ethernet (registered trademark) work network when layer 2 switching is performed. This network is obtained by rearranging the partial packet networks 102-1 to 102-5 of the Ethernet (registered trademark) work network 102 shown in FIG. 1 and a plurality of user channels multiplexed in the same packet related to the present embodiment. Cross-connect devices 201-1 and 20-2 for transferring to the same route, and multiplexers 202-1, 2 and 3 for multiplexing signals of a plurality of user channels in the same packet. In the figure, an L2A layer 203 and L2B layers 204-1 and 204-2 are shown. Here, L2 (layer 2) is further divided into an L2A layer and an L2B layer. The L2A layer refers to a layer that is transmitted end-to-end between layer 2 switches, and the L2B layer is a multiplexing device. A layer terminated between cross-connect devices.

  Multiplexers 202-1, 2 and 3 multiplex Ethernet frames, and the multiplexed data is sent to cross-connect devices 201-1 and 201-2 directly or by partial packet networks 102-1 to 102-5. Connected. The cross-connect devices 201-1 and 201-2 perform layer 2 switching. The transmission of the switching information is performed by the additional information of the L2B layer, and the additional information is terminated and generated in the cross-connect devices 201-1 and 201-2. The L2A layer additional information is transparent in the cross-connect devices 201-1 and 201-2, and terminated and generated in the STM-IP conversion devices 103-1 and 103-2.

  FIG. 3 is a block diagram showing a network configuration in the IP packet network when layer 3 switching is performed. This network is a partial packet network 102-6-10 of the IP packet network 102 shown in FIG. 1, and a plurality of user channels multiplexed in the same packet related to the present embodiment are rearranged and transferred to another route. Cross-connect devices 201-3, 4 and L3 switches 301-1, 2 provided. In the figure, L3B layers 302-1 to 30-3 and L3A layer 303 are shown. Here, L3 (layer 3) is further divided into an L3A layer and an L3B layer. The L3A layer refers to a layer that passes through the IP packet network from end to end, and the L3B layer refers to a layer that is terminated between L3 switches.

  The partial packet networks 102-6 to 10 are connected to the cross-connect devices 201-3 and 4 and perform Ethernet frame switching. The switched data is connected to the L3 switches 301-1 and 301-2. The L3 switches 301-1, 2 perform L3 switching. The transmission of the switching information is performed by the additional information of the L3B layer, and the additional information is terminated and generated in the L3 switches 301-1 and 301-2. The L3A layer information is transparent in the cross-connect device, and terminated and generated in the STM-IP conversion devices 103-1 and 103-2.

  FIG. 4 shows the format of an Ethernet (registered trademark) frame or IP packet passing through an Ethernet (registered trademark) work network or an IP packet network. The L3A layer includes an L3 header 405-1, L3A additional information 404, L3B additional information 403-1, an L2 information storage area 402-1 and an L3 trailer 401-1. The L3B layer includes an L3 header 405-2, L3B additional information 403-2, an L2 information storage area 402-2, and an L3 trailer 401-2. The L2A layer includes an L2 header 409-1, L2A additional information 408, L2B additional information 407-1, a TDM information storage area 406-1, and an L2 trailer 410-1. The L2B layer includes an L2 header 409-2, L2B additional information 407-2, a TDM information storage area 406-2, and an L2 trailer 410-2.

  In the L2B layer, TDM information is stored in the TDM information storage area 406-2, L2B additional information 407-2 is added immediately before the TDM information storage area 406-2, and an L2 header 409-2 and trailer are added at the top. L2 trailer 410-2 is added to the part. In the L2A layer, L2A additional information 408 is added immediately before the L2B additional information 407-1 and the TDM information storage area 406-2 received from the L2B layer, the L2 header 409-1 is added to the head portion, and the L2 is added to the trailer portion. A trailer 410-1 is added. In the L3B layer, the information received from the L2A layer is stored in the L2 information storage area 402-2, the L3B additional information 403-2 is added immediately before, the L3 header 405-2 at the head, and the L3 trailer 401- at the trailer section. 2 is added. In the L3A layer, the L3A additional information 404 is added immediately before the L3B additional information 403-1 and L2 information storage area 402-1 received from the L3B layer, the L3 header 405-1 at the head, and the L3 at the trailer. A trailer 401-1 is added.

  FIG. 5 shows the contents of information to be added in each layer. Additional information 508, sequence number (SN) 501 for detecting packet loss, duplication, and reordering, pointer (PTR) 502 indicating the start position of TDM information, physical layer alarm for transmitting TDM multiple lines Indicates an alarm (ALM) 503, error information (ERR) 504 for transmitting line quality at the physical layer, a label (LABEL) 505 indicating a multiplexing method of multiplexed TDM information, and the length of the TDM information. Length information (LEN) 506 is included.

FIG. 6 shows a method for encapsulating TDM information.
507 in FIG. 5 and FIG. 6 are conceptually equivalent to each other in terms of L2B additional information. However, in FIG. 5, only six pieces of information below SN are listed as examples, whereas in FIG. 6, only two of SN and PTR are listed as examples. The additional information is not limited to this, and an appropriate type or number can be used.

  It includes an Ethernet (registered trademark) frame structure 601, a MAC preamble 601-1, a payload 601-2, and an EOF (End of Frame) 601-3. The frame 602 describes the contents of the payload 601-2. DA (Destination Address) 602-1, SA (Source Address) 602-2, TYPE 602-3, MAC Payload 602-4, FCS (Frame Check Sequence) 602 5 is included. A frame 603 shows the contents of the MAC Payload 602-4, and includes a Synchronous header 603-1 and a Synchronous payload 603-2.

  A frame 605 indicates a TDM signal. VC11 (1) 605-1, VC11 (2) 605-2, and VC11 (3) 605-3 are transmitted in the order of VC11 (1) to (3). Indicates that A frame 604 shows a frame configuration for the i-th TDM signal. The MAC header 604-1, SN (Serial Number) 604-2, PTR (Pointer) 604-3, VC11 (1) 604-4, VC11 (2-1) Including 604-5 and EOF604-6. A frame 606 shows a frame configuration for the (i + 1) -th TDM signal. The MAC header 606-1, the SN (serial number) 606-2, the PTR (pointer) 606-3, and the VC11 (2-2) 606 -4, VC11 (3) 606-5, and EOF606-6.

  In the payload in the frame 601 of FIG. 6, the MAC header to VC11 (2-1) of the frame 604 are stored. The EOF of the frame 601 and the EOF of the frame 604 are the same. Note that DA + SA + Type in the frame 602 matches the MAC header of the frame 604. The L2B of the L2B frame is the MAC header of the frame 604 (= DA + SA + Type of the frame 602), the L2B additional information of the L2B frame is the SN + PTR of the frame 604, and the TDM storage information of the L2B frame is the VC11 (1) of the frame 604 + VC11 (2-1), the L2 trailer of the L2B frame corresponds to the EOF of the frame 604. Here, only the L2B frame of FIG. 4 is taken up in the embodiment of FIG. Note that L2A and L3 additional information can be similarly applied.

  In the i-th frame, the remaining VC11 (1) signal that could not be accommodated in the (i-1) th frame is multiplexed in the payload portion, and when the multiplexing of the VC11 (1) signal is completed, a gap is left. The VC11 (2) is immediately accommodated without any problems. The head of VC11 (2) is indicated by a pointer 604-3 that is a part of the additional information 507. If all the information of VC11 (2) is not multiplexed in the frame, the multiplexing of information is interrupted and EOF 604-6 is inserted. The remaining VC11 (2) information is multiplexed from the beginning of the payload portion of the (i + 1) th frame, and when the multiplexing of the VC11 (2) signal is completed, the VC11 (3) can be immediately accommodated without leaving a gap. Done. The head of VC11 (3) is indicated by a pointer 606-3 that is a part of the additional information 507. For the subsequent frames, similarly, the multiplexing of the information is interrupted in the middle, the multiplexing is performed from the beginning of the next frame, the multiplexing is completed, and the multiplexing start point of the next TDM signal is designated by the pointer.

  FIG. 7 shows the configuration of the STM-IP conversion apparatus. The STM-IP conversion apparatus 103 converts fixed band signals into packet signals and vice versa, and embeds maintenance management information that communicates the communication state of the transmission section as additional information inside the packet format data. This is a transmission device.

  The STM-IP conversion apparatus 103 includes a fixed band signal termination unit 801, an information storage buffer 802, an OAM information detection unit 803, a synchronous read control unit 804, a frame counter 805, an additional information assembly unit 806, a multiplexing unit 807, and a MAC frame assembly unit. 808, physical interface unit 809, OAM information adding unit 810, additional information separation unit 811, separation unit 812, MAC frame termination unit 813, physical interface unit 814, fixed band signal termination unit 815, information storage buffer 816, synchronous read control unit 817, an interface unit 821, a data buffer unit 822, a data buffer unit 823, a subframe assembly unit 824, a subframe termination unit 825, a packet assembly unit 826, and a packet termination unit 827.

  The fixed band signal termination unit 801 terminates the fixed band signal and separates it into main signal information and maintenance management information. The information storage buffer 802 receives and stores main signal information from the output of the fixed band signal termination unit 801. The OAM information detection unit 803 detects maintenance management information from the output of the fixed band signal termination unit 801. The synchronous reading control unit 804 controls reading of the main signal information of the fixed band signal from the information storage buffer 802. The additional information assembling unit 806 transmits an alarm or channel quality for transmitting an alarm in a physical layer in a time division multiplexing line based on information output from the OAM information detecting unit 803 and the synchronous readout control unit 804. Additional information to be added to the packet signal is generated, including communication state display information regarding the error for the purpose and a pointer indicating the head position of the fixed band signal. The MAC frame assembling unit 808 includes data of a predetermined length obtained by multiplexing or demultiplexing the fixed band signal output from the information storage buffer 802 and additional information output from the additional information assembling unit 806 in the payload, and includes routing information. A header is added to assemble a frame and output as a packet signal.

  The MAC frame termination unit 813 terminates the packet signal. The additional information separating unit 811 terminates the additional information of the packet signal received by the MAC frame terminating unit 813. The information storage buffer 816 receives and stores main signal information of the packet signal received by the MAC frame termination unit 813. The synchronous read control unit 817 controls reading of the fixed band signal from the information storage buffer 816. The OAM information adding unit 810 assembles maintenance management information based on the information received from the OAM information detecting unit 803 and the additional information separating unit 811. The fixed band signal termination unit 815 assembles a fixed band signal based on the main signal information read from the information storage buffer 816 and the maintenance management information received from the OAM information adding unit 810 and sends it out.

  The MAC frame terminator 813 complements, as an information channel, a termination function for verifying the order of the numbers in the received sequence number information, and the frame data corresponding to the missing sequence number information when the skip of the sequence number information is detected. A data complementing function and a data discarding function for discarding frame data corresponding to the duplicated sequence number when the duplication of sequence number information is detected can be provided.

  The synchronous read control unit 817 monitors the data amount per unit time of the packet data on the input side and the fixed band signal on the output side of the information storage buffer 816 in the process of converting the packet signal into the fixed band signal. In the case where an imbalance is detected, a failure in the transmission section can be detected. The synchronous read control unit 817 monitors the reception cycle or data queue length of the packet format data on the input side of the information storage buffer 816 in the process of converting the packet signal to the fixed band signal, and the reception cycle is fixed. A failure in the transmission section can be detected when the expected value of the reception cycle derived from the bandwidth of the bandwidth information or the upper limit or lower limit of the data queue length deviates beyond the allowable range.

  The OAM information detecting unit 803, the additional information assembling unit 806, and / or the OAM information adding unit 810 convert the alarm state of the physical interface unit into a communication enable / disable state of the information channel and transmit it in the information transmission direction, and forward alarm information Based on the information, it is possible to generate backward alarm information that informs the opposite side of the communication availability state and include it as communication state display information of additional information. The OAM information detection unit 803 includes a table that stores an output alarm and an output direction for input information, generates maintenance management information with reference to the table, and adds an additional information assembly unit 806 or an output corresponding to the output direction. Maintenance management information can be output to the OAM information adding unit 810.

  In the configuration as described above, the TDM signal input to the fixed band signal termination unit 801 is sent by separating information related to the main signal to the information storage buffer 802 and information related to alarm information to the OAM information detection unit 803. . For example, the information stored in the information storage buffer 802 is read by the synchronous read control 804 at a cycle that is an integral multiple of 125 μsec, which is the multiplexing cycle of the STM signal. The additional information assembling unit 806 receives the OAM information from the OAM information detecting unit 803 and generates OAM additional information to be added to the Ethernet frame. Also, the information related to multiplexing of the TDM signal and the head signal is received from the synchronous read control unit 804, and OAM additional information such as a sequence number and a pointer is generated. The OAM additional information includes, for example, the sequence number, pointer, alarm (alarm), error information, label, length, and the like described in FIG. 5. In the present embodiment, a detailed embodiment of alarm information is mainly described. Will be explained later. The data read from the information storage buffer 802 and the information assembled by the additional information assembling unit 806 are multiplexed by the multiplexing unit 807, assembled into a MAC frame by the MAC frame assembling unit 808, and the packet is transmitted via the physical interface unit 809. Sent to the network.

On the other hand, the packet signal input to the physical interface unit 814 is MAC-terminated by the MAC frame termination unit 813, and the information related to the main signal is separated into the information storage buffer 816 and the information related to the alarm information is separated into additional information by the separation unit 812. It is separated into a part 811. The information storage buffer 816 is read by the timing control by the synchronous read control 817. The OAM information adding unit 810 assembles OAM information based on the information received from the OAM information detecting unit 803 and / or the additional information separating unit 811 and sends the information to the fixed band signal terminating unit 815. The fixed band signal termination unit 815 assembles the information read from the information storage buffer 816 and the information received from the OAM information adding unit 810 into a TDM signal and sends it to the TDM network.
The additional information can further include sequence number information for detecting missing, duplicated, or rearranged frames. The additional information can further include signal label information indicating a multiplexing method of the information channel. The additional information further includes frame length information indicating the information length of the frame, and the MAC frame terminating unit 813 can identify a plurality of frames with reference to the frame length information. The additional information can include front warning information for notifying the communication state in the signal transmission direction and rear warning information for notifying the communication enable / disable state to the opposite side based on the front warning information.

  The signal label information added by the MAC subframe assembling unit 808 can include band information indicating the band of the information channel multiplexed in the subframe. The signal label information can include multiplexed frame number information indicating the number of periodic frames on the fixed band side of the information channel multiplexed in the subframe.

  The format of the packet assembled by the MAC frame assembling unit 808 and terminated by the MAC frame terminating unit 813 may be a MAC frame defined by IEEE 802.3 or an IP frame defined by RFC 0791 of IETF.

  FIG. 8 shows an operation example of the multiplexing apparatus. In the figure, a multiplexer 202, Ethernet frames 701 and 702, STM information 701-1 and 702-1 in the Ethernet frame, MAC headers 701-2 and 702-2, and a label 703-1 assigned in the multiplexer. 2, a multiplexing unit 704, a MAC header 705, and a multiplexed Ethernet frame 706 are shown.

  The Ethernet frames 701 and 702 have the MAC headers 701-2 and 702-2 terminated by the multiplexing device 202, and labels 703-1 and 703-2 are added to the heads of the STM information 701-1 and 702-1. The data is multiplexed by the multiplexing unit 704, added with the MAC header 705, and transmitted from the multiplexing device 202.

  FIG. 9 shows the configuration of the multiplexing apparatus. In order to realize the operation described with reference to FIG. 8, the multiplexing apparatus 202 includes a VLAN frame termination unit 951-1 and 2, an OAM information separation unit 952-1 and 2, information storage buffers 953-1 and 2, and synchronous read control. 954-1, 95, additional information assembly units 955-1, 955-2, multiplexing units 956-1, 956-1, frame counter 957, multiplexing unit 958, and VLAN frame assembly unit 959.

  The Ethernet frames input to the VLAN frame termination units 951-1 and 951-2 have information related to the main signal portion stored in the information storage buffers 953-1 and information stored in the alarm information in the OAM information detection units 952-1 and 952- To be separated. The information storage buffers 953-1 and 953-1 and 953-1 are read out with the timing controlled by the synchronous read controls 954-1 and 952-1. The additional information assembly units 955-1 and 955-2 assemble additional information based on the information received from the OAM information detection units 952-1 and 95-2. The multiplexing units 956-1 and 966-1 and multiplex the information read from the information storage buffers 953-1 and 953 and the information received from the additional information assembling units 955-1 and 955-2. The multiplexing unit 958 multiplexes the information received from the multiplexing units 956-1 and 956-1 and sends it to the VLAN frame assembling unit 959. The VLAN frame assembling unit 959 adds a VLAN tag to the information received from the multiplexing unit 958 and sends a signal to the packet network.

  FIG. 10 shows an operation example of the cross-connect device. In the figure, Ethernet frames 901, 902, 906, 907, STM information 901-1, 901-3, 902-1, 902-3, labels 901-2, 901-4, 902-1, 902-4, MAC header 901-5, 902-5, a separation unit 903, a switch unit 904, a multiplexing unit 905, MAC headers 906-1 and 907-1, and a cross-connect device 201 are shown.

  The cross-connect device 201 separates the MAC headers of the input Ethernet frames 901 and 902 by the separation unit 903, and separates them into labels and STM information. The switch unit 904 performs switching using a label. The multiplexing unit 905 multiplexes the switched information, adds a MAC header, generates Ethernet frames 906 and 907, and sends them to the packet network.

  FIG. 11 shows a configuration example of the cross-connect device. In order to realize the operation described with reference to FIG. 10, the cross-connect device includes subframe separation units 1001-1 and 1002, switch control information addition units 1002-1 and 1002, frame switch 1003, and switch control information deletion unit 1004-1. 2, a subframe assembly unit 1005-1, a subframe separation unit and switch control information addition unit 1114, packet termination units 1010-1 and 2, and packet assembly units 1011-1 and 101-1.

  The subframe demultiplexing units 1001-1 and 1002-1 and 2 decompose the subframes received from the packet termination units 1010-1 and 1010-1 and send them to the switch control information adding units 1002-1 and 1002-1. The switch control information addition units 1002-1 and 1002-1 and 2 add the switch control information to the information received from the subframe separation units 1001-1 and 2 and send the information to the frame switch 1003. The frame switch 1003 performs packet switching according to the switch control information. The switch control information deleting units 1004-1 and 2 receive the switched packet from the frame switch, delete the switch control information, and send it to the subframe assembling units 1005-1 and 1005-2. The subframe assembling units 1005-1 and 1005-2 assemble the information received from the switch control information deleting unit into subframes, and send the subframes to the packet network via the packet assembling units 1011-1 and 101-1.

  FIG. 12 shows a detailed configuration example of the subframe separation unit and the switch control information addition unit described in FIG. The subframe separation unit 1001 includes a separation unit 1101, an OAM information detection unit 1103, a switch control information detection unit 1104, and a control timing generation unit 1105. The switch control information detection unit 1002 includes an information storage buffer 1106, a synchronous read control 1107, a switch control information assembly unit 1108, an OAM information assembly unit 1109, a control timing generation unit 1110, a multiplexing unit 1111, a subframe separation unit 1001, and a switch control. An information adding unit 1002 is provided.

  The separation unit 1101 separates information related to the main signal into the information storage buffer 1106, switch control information into the switch information detection unit 1104, and information related to alarm information into the OAM information detection unit 1103. The OAM information detection unit 1103 detects an alarm. The switch information detection unit 1104 detects switch control information and sends the information to the switch control information assembly unit 1108. The information storage buffer 1106 is read by the synchronous read control unit 1107 with timing control. The OAM information assembly unit 1109 assembles OAM information to be added. The multiplexing unit 1111 multiplexes the information read from the information storage buffer 1106, the switch control information assembled from the switch control information assembly unit 1108, and the OAM information assembled by the OAM information assembly unit 1109, To send.

  FIG. 13 shows an example of alarm transfer in the STM-IP conversion apparatus. As shown in the figure, it is connected to the conversion device 103, the STM network 101, and the packet network 102. In the figure, each node has an AIS (Section) reception 1207, an REC reception 1208, an AIS (Channel) reception 1209, an AIS (Channel) generation 1210, a BAIS (Channel) generation 1211, a BAIS (Channel) reception 1212, and an AIS (Channel) reception. 1213, BAIS (Section) generation 1214, BUF (Buffer UnderFlow) detection 1216, BOF (Buffer OverFlow) detection 1217, LFC detection 1218, and Link break detection 1219. Note that ● indicates detection, and ○ indicates generation.

  When the STM-IP conversion apparatus 103 receives AIS (Section) 1207 and REC 1208, it detects respective alarms, detects AIS (Channel) 1209, generates AIS (Channel) 1210, and generates packet network 102. Send an alarm to This operation is processed by the OAM information detection unit 803 in FIG.

  FIG. 15 shows a correspondence table for output alarms and output directions for input information in the OAM information detection unit 803. As shown in the figure, the OAM information detection unit 803 includes a table that outputs a transfer alarm determined for an input alarm. This table is realized in the form of a memory table or a combinational logic circuit.

  Here, AIS is an alarm indicating that a failure has occurred in the upstream of transmission and a normal signal cannot be transferred downstream (forward direction). Section is a unit of transmission stretched between adjacent transmission devices. is there. That is, AIS (Section) is an alarm for notifying downstream that a failure in units of Section has occurred in an upstream transmission apparatus. Further, the channel is a transmission unit for communicating between end users through the network, and the AIS (channel) is an alarm for notifying the downstream that a failure in the channel unit has occurred in the upstream transmission apparatus. Since a plurality of channels are multiplexed inside the network and grouped as a section, when a failure in a unit of section occurs in the transmission apparatus, the failure spreads to all the multiplexed channels, so the corresponding AIS (channel) ) Is sent downstream. REC is an alarm detected by the receiving unit of the transmission apparatus, and corresponds to a reception signal disconnection or the like. Even when the transmission apparatus detects REC, since the failure affects all multiplexed channels, the corresponding AIS (channel) is sent downstream.

  In addition to the above, the STM-IP conversion apparatus 103 generates a BAIS (Section) 1214 and sends an alarm to the STM network 101. Here, BAIS uses a reverse link extending toward the upstream device to notify the upstream device that a failure has occurred in the reverse link. When the transmission apparatus detects AIS (Section) or REC, BAIS is transmitted in the upstream direction (backward direction).

  Further, the conversion device 103 detects an alarm when receiving BAIS (Channel) 1212 from the packet network 102. Here, since BAIS (Channel) indicates that a failure has occurred in the upstream reverse link in units of channels, it is detected as a failure, but no further alarm transfer is performed.

  When receiving the link disconnection 1219 from the packet network 102, the conversion apparatus 103 detects a link disconnection alarm and simultaneously detects a BUF alarm and an LFC alarm. When receiving the BUF 1216, the BOF 1217, and the LFC 1218 from the packet network 102, the conversion device 103 detects the respective alarms, detects the AIS (Channel) 1213 alarm, generates the BAIS (Channel) 1211 alarm, and generates the packet. Send to network 102. Here, the link disconnection alarm is an alarm indicating an abnormality of the link detected by the optical power disconnection or the like. The BUF alarm is an alarm indicating that the information storage buffer is emptied when an input packet does not arrive and is in an underflow state where there is no signal to be read periodically. Conversely, the BOF alarm is an alarm that indicates a state in which information cannot be periodically read from the information storage buffer and the buffer overflows. The LFC is an alarm indicating that the received frame has not been received correctly. As an example of the LFC alarm in the packet network, it is possible to detect that a frame is interrupted because a packet scheduled to arrive periodically does not arrive beyond a predetermined detection time. When the conversion device 103 detects a link disconnection alarm, the frame cannot be received and a buffer underflow occurs. Therefore, BUF and LFC are transmitted to the subsequent stage. Since multiplexed channels cannot be transferred, AIS (channel) and BAIS (channel) are transmitted.

FIG. 16 shows a circuit example for detecting BOF and BUF. The synchronous read control unit 817 that controls the information storage buffer 816 in FIG. 7 includes a write address instruction unit 1501, a read address instruction unit 1502, a period counter 1503, a subtracter 1504, and a comparator 1505. Since the write address instruction unit 1501 and the read address instruction unit 1502 operate at a constant period based on the periodic signal output from the period counter 1503, the length of the information stored in the information storage buffer 816 is a deviation due to fluctuation. It is basically a constant value except for. When the input to the information storage buffer 816 stops, the write address instruction unit 1501 stops the write operation due to the absence of a signal to be written, and thus the output of the subtractor 1504 exceeds the determination threshold value a. The device 1505 detects BUF. When the output from the information storage buffer 816 stops, the read address instruction unit 1502 stops the read operation due to the absence of a signal to be read, and thus the output of the subtractor 1504 exceeds the determination threshold value b, so that the comparator 1505 detects BOF.
FIG. 14 shows another example of alarm transfer in the STM-IP conversion apparatus. In the figure, an IP P-AIS generation 1301, an IP P-BAIS generation 1302, an IP P-BAIS reception 1303, and an IP P-AIS reception 1304 are shown. These alarms are the alarms that were treated as channel alarms in FIG. 13 and redefined as alarms for paths established by IP links.

  Specific differences between FIG. 13 and FIG. 14 will be described below. When the AIS (Section) 1207 alarm or the REC 1208 alarm is detected, the conversion apparatus 103 generates an IP P-AIS 1301 alarm and sends it to the packet network 102. The converter 103 detects an IP P-BAIS 1303 alarm when receiving IP P-BAIS from the packet network 102. When receiving the IP P-AIS 1304 alarm, the BUF 1216 alarm, the BOF 1217 alarm, and the LFC 1218 alarm, the conversion apparatus 103 generates an IP P-BAIS 1302 and sends the alarm to the packet network 102.

  According to the present invention, it is possible to accommodate a conventional voice, dedicated line, and ATM service in a data network such as an IP-VPN network or a wide area Ethernet network, and the cost of possessing both the conventional network and the data network. The burden can be reduced.

It is one Example of the block which shows the structure of the network by embodiment of this invention. 1 is an example of a block showing a network configuration in an Ethernet (registered trademark) work network when performing layer 2 switching according to the present invention; 1 is an example of a block showing a network configuration in an IP packet network when performing layer 3 switching according to the present invention. 2 is an example of a format of an Ethernet® frame or an IP packet passing through an Ethernet® work network or an IP packet network. It is one Example of the content of the information added by each layer. It is one Example which showed the method of encapsulation of TDM information. It is one Example of a structure of a STM-IP conversion apparatus. It is one Example of the operation | movement content of a multiplexing apparatus. It is one Example of the structure of a multiplexing apparatus. It is one Example of the operation | movement content of a cross-connect apparatus. It is one Example of a structure of a cross-connect apparatus. It is one Example of a structure of a sub-frame separation part and a switch control information addition part. It is one Example of the alarm transmission in a STM-IP conversion apparatus. It is one Example of the alarm transmission in a STM-IP conversion apparatus. It is one Example of an OAM information detection part. It is one Example of the circuit which detects BOF and BUF.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 ... Conventional STM network 102 ... Ethernet (trademark) work network or IP packet network 103 ... STM-IP converter 104 ... Terminal 105 connected to STM network ... Ethernet (trademark) work network or IP packet network Connected terminal 201 ... cross-connect device 202 ... multiplexer 203 ... L2A layer 204 ... L2B layer 301 ... L3 switch 302 ... L3B layer 303 ... L3A layer 401 ... L3 trailer 402 ... L2 information storage area 403 ... L3B additional information 404 ... L3A additional information 405 ... L3 header 406 ... TDM information storage area 407 ... L2B additional information 408 ... L2A additional information 409 ... L2 header 410 ... L2 trailer 501 ... Sequence number 502 ... Pointer 503 ... Alarm 504 ... Error information 505 ... Label 506 ... Length 508 ... additional information overall 601 ... Ethernet frame structure 601-1 ... MAC preamble 601-2 ... payload 601-3 ... EOF
602 ... Contents of payload 602-1 ... DA
602-2 ... SA
602-3 ... TYPE
602-4 ... MAC Payload
602-5 ... FCS
603 ... Contents of MAC Payload 603-1 ... Synchronous header
603-2 ... Synchronous payload
604 ... i-th frame configuration 604-1 ... MAC Header
604-2 ... SN
604-3 ... PTR
604-4 ... VC11 (1)
604-5... VC11 (2-1)
604-6 ... EOF
605 ... TDM signal 605-1 ... VC11 (1)
605-2 ... VC11 (2)
605-3 ... VC11 (3)
606 ... (i + 1) -th frame configuration 606-1 ... MAC Header
606-2 ... SN
606-3 ... PTR
606-4 ... VC11 (2-2)
606-5 ... VC11 (3)
606-6 ... EOF
801 ... Fixed band signal termination unit 802 ... Information storage buffer 803 ... OAM information detection unit 804 ... Synchronous read control 805 ... Frame counter 806 ... Additional information assembly unit 807 ... Multiplexing unit 808 ... MAC frame assembly unit 809 ... Physical interface unit 810 ... OAM information addition unit 811 ... additional information separation unit 812 ... separation unit 813 ... MAC frame termination unit 814 ... physical interface unit 815 ... fixed band signal termination unit 816 ... information storage buffer 817 ... synchronous read control unit 821 ... interface unit 822 ... data Buffer unit 823 ... Data buffer unit 824 ... Subframe assembly unit 825 ... Subframe termination unit 826 ... Packet assembly unit 827 ... Packet termination unit 701 ... Ether frame 701-1 ... STM information 701-2 ... MAC header 702 ... Etherframe 7 2-1, STM information 702-2, MAC header 703-1, label 703-2, label 704, multiplexing unit 705, MAC header 706, Ethernet frame 951, VLAN frame termination unit 952, OAM information separation unit 953, information Storage buffer 954 ... Synchronous readout control 955 ... Additional information assembly unit 956 ... Multiplexing unit 957 ... Frame counter 958 ... Multiplexing unit 959 ... VLAN frame assembly unit 901 ... Ether frame 901-1 ... STM information 901-2 ... Label 901-3 ... STM information 901-4 ... label 901-5 ... MAC header 902 ... Ethernet frame 902-1 ... STM information 902-2 ... label 902-3 ... STM information 902-4 ... label 902-5 ... MAC header 903 ... separating unit 904 ... Switch unit 905 ... Multiplexing unit 906 ... Ether frame 90 -1 ... MAC header 907 ... Ethernet frame 907-1 ... MAC header 1001 ... subframe separation unit 1002 ... switch control information addition unit 1003 ... frame switch 1004 ... switch control information deletion unit 1005 ... subframe assembly unit 1010 ... packet termination unit 1011: Packet assembly unit 1101 ... Separation unit 1103 ... OAM information detection unit 1104 ... Switch control information detection unit 1105 ... Control timing generation unit 1106 ... Information storage buffer 1107 ... Synchronous read control 1108 ... Switch control information assembly unit 1109 ... OAM information assembly Unit 1110 ... Control timing generation unit 1111 ... Multiplexer 1114 ... Subframe separation unit and switch control information addition unit 1207 ... AIS (Section) reception 1208 ... REC reception 1209 ... AIS (Channel) reception 1210 ... AIS (Channel) generation 1211 ... BAIS (Channel) generation 1212 ... BAIS (Channel) reception 1213 ... AIS (Channel) reception 1214 ... BAIS (Section) generation 1216 ... BUF detection 1217 ... BOF detection 1218 ... LFC detection 1219 ... Link Disconnection detection 1301 ... IP P-AIS generation 1302 ... IP P-BAIS generation 1303 ... IP P-BAIS reception 1304 ... IP P-AIS reception 1501 ... Write address instruction unit 1502 ... Read address instruction unit 1503 ... Period counter 1504 ... Subtraction 1505 ... Comparator

Claims (10)

A transmission device for converting a fixed band signal into a packet signal and vice versa, and for embedding maintenance management information that communicates the communication state of the transmission section with each other as additional information inside the packet format data,
A first fixed band signal terminator that terminates the fixed band signal and separates into main signal information and maintenance management information;
A first information storage buffer for receiving and storing main signal information from the output of the first fixed band signal termination unit;
A first synchronous read control unit for controlling reading of main signal information of a fixed band signal from the first information storage buffer;
A maintenance management information detection unit for detecting maintenance management information from the output of the first fixed band signal termination unit;
Communication related to an alarm for transmitting a warning in a physical layer in a time division multiplexing line or an error for transmitting a line quality based on information output from the maintenance management information detection unit and the first synchronous read control unit An additional information assembling unit that generates additional information to be added to the packet signal, including state display information and a pointer indicating a head position of the fixed band signal;
A predetermined length of data obtained by multiplexing or separating the fixed band signal output from the first information storage buffer and additional information output from the additional information assembly unit are included in the payload, and a header including routing information is added. A frame assembly unit for assembling a frame and outputting it as a packet signal;
A frame termination for terminating the packet signal;
An additional information separation unit that terminates additional information of the packet signal received by the frame termination unit;
A second information storage buffer for receiving and storing main signal information of the packet signal received by the frame termination unit;
A second synchronous read control unit for controlling reading of a fixed band signal from the second information storage buffer;
Based on the information received from the maintenance management information detection unit and the additional information separation unit, a maintenance management information giving unit that assembles maintenance management information;
A second fixed band signal terminating unit that assembles and transmits a fixed band signal based on main signal information read from the second information storage buffer and maintenance management information received from the maintenance management information giving unit;
The transmission apparatus comprising:   The transmission apparatus according to claim 1, wherein the additional information further includes sequence number information for detecting frame loss, duplication, or order change.   2. The transmission apparatus according to claim 1, wherein the additional information further includes signal label information indicating an information channel multiplexing method. The transmission apparatus according to claim 1, wherein the additional information further includes frame length information indicating an information length of a frame,
The frame termination unit is a transmission device that identifies a plurality of frames with reference to the frame length information.   The transmission apparatus according to claim 1, wherein the additional information includes front warning information for notifying a communication state in a signal transmission direction and rear warning information for transmitting a communication availability state to the opposite side based on the front warning information. Transmission equipment.   The transmission apparatus according to claim 1, wherein the maintenance management information detection unit, the additional information assembly unit, and / or the maintenance management information addition unit converts an alarm state of a physical interface unit into a communication availability state of an information channel. A transmission device that generates forward alarm information transmitted in an information transmission direction and rear alarm information that transmits a communication enable / disable state to the opposite side based on the front alarm information and includes the information as communication state display information of additional information. The transmission apparatus according to claim 1, wherein the frame termination unit is
A termination function for verifying the order of the numbers in the received sequence number information;
A data complementing function that complements the data of the frame corresponding to the missing sequence number information as an information channel when the skip of the sequence number information is detected,
A transmission apparatus provided with a data discard function for discarding frame data corresponding to a duplicate sequence number when duplication of sequence number information is detected.   2. The transmission apparatus according to claim 1, wherein the second synchronous read control unit is a process of converting a packet signal into a fixed-band signal, and the packet format data on the input side and the output side of the second information storage buffer. A transmission device that monitors the amount of data per unit time of fixed-band signals and detects a failure in a transmission section when an imbalance is detected.   2. The transmission device according to claim 1, wherein the second synchronous read control unit is a process of converting a packet signal into a fixed band signal, and receives a packet format data reception cycle on the input side of the second information storage buffer or A transmission device that monitors the data queue length and detects a failure in the transmission section when the reception cycle deviates beyond the allowable range from the expected value of the reception cycle derived from the fixed bandwidth information band or the upper or lower limit of the data queue length . The transmission apparatus according to claim 1, wherein the maintenance management information detection unit includes a table storing an output alarm and an output direction with respect to input information, generates maintenance management information with reference to the table, and corresponds to the output direction Then, a transmission device that outputs maintenance management information to the additional information assembling unit or the maintenance management information adding unit.

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