JP2714028B2 - LAN node and LAN system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial applications]

The present invention relates to a ring LAN system and a node configuration thereof, and more particularly, to a switching system in a multiple ring LAN node suitable for high-speed operation.

[Prior art]

For a conventional multi-ring LAN node, for example, the node structure is described in IE85-124 of the Institute of Electronics, Information and Communication Engineers Exchange Study Group, and the switching system is described in JP-A-61-163753.

[Problems to be solved by the invention]

In the above conventional method, in an n-multiplex ring configuration in which a plurality of nodes are connected by a plurality of slotted rings, each node once receives a slot on each ring in a buffer memory corresponding to the ring, and then automatically receives the slot in the buffer memory. Selects a slot addressed to the node. Also, at the time of transmission, information to be transmitted by each node is redundantly stored in the transmission buffer memory of each ring, and transmitted without duplication using the empty slot acquired first. According to the above method, each node needs a total of 2n outputs, n outputs for relaying on the ring and n outputs for the receiving buffer corresponding to the ring. The value of n is generally 16 to 32
Therefore, in the conventional method, there is a problem that the number of nodes increases / decreases in the number of nodes and the amount of hardware increases drastically, and the use efficiency of the transmission buffer decreases. An object of the present invention is to suppress an increase in the amount of hardware of the multiple ring LAN node described above.

[Means for Solving the Problems]

The conventional problem described above is caused by providing a plurality of transmission / reception function units corresponding to each ring in the ring access function unit in each node, and giving the transmission / reception function unit a substantial exchange function. Therefore, in the present invention, each node is provided with a transmission / reception function unit addressed to the own node common to the ring, the ring access function unit is provided with an exchange function, and relay and reception of slot information are determined on the node. Achieve the above objectives.

[Action]

According to the present invention, (the number of inputs) × (the number of outputs)
By providing an N × L switch corresponding to the above, it is possible to exchange the reception slot information from each ring to the own node (reception) and the other node (relay) using the slot header. Furthermore, at the time of slot information transmission, transmission can be performed from one transmission buffer to an arbitrary ring. Also, at the time of the above transmission, transmission efficiency can be improved if control is performed to transmit to the ring with the lowest traffic, and if control is performed to transmit to a specific ring corresponding to the destination node, the reception node is controlled. In this case, since the signal is received only from a specific ring, the maximum receiving speed is limited to one ring speed, so that the node operating speed can be reduced. Further, according to the present invention, at the time of system setting, a call number capable of identifying a transmission source and a destination is provided between communication nodes in an out-of-band manner, so that the call number is used as switch information in a slot header during subsequent data transfer. Can be. In addition, priority information is provided in the slot header, high priority is controlled so as to perform all processing, and the priority of the relay slot is made higher than that of the transmission slot, so that the delay in the node due to the relay can be reduced. it can.

【Example】

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 2 is an overall configuration diagram of a network system to which the present invention is applied, in which an upper LAN 201 including LAN nodes 1, 2, 3, and 4 and a transmission line 220 is replaced by lower LANs 202 and 203 and a camera 21.
Accommodates 4 and monitor 215. Also, the lower LANs 202 and 207
, LAN terminals 212 and 213 and 211 and 210 are connected via nodes 204 and 205 and 206 and 207, respectively.
The present invention relates to a host LAN 2 in the above network system.
This relates to the structure of 01 and the nodes 1, 2, 3, and 4 connected thereto, and the connection media type is not essential. FIG. 1 shows the structure of the node 1. The node 1 is connected to a transmission line 220 composed of an optical fiber via an optical / electrical converter 12 and an electrical / optical converter 15. LAN frames are
It consists of 15 channels, a separating unit 13 for separating the frame header and dividing the channel, a multiplexing unit 14 for reproducing, and a 16 × 16 switch for exchanging the channel unit.
10 and a user device interface 11. Of the 16 inputs and outputs of each switch 10, 15 each indicated by 22 and 23
Are connected to the separation unit 13 and the multiplexing unit 14, respectively,
One input / output, indicated by reference numerals 20 and 21, is connected to the user device interface 11. The exchange and transmission / reception procedures in the switch 10 will be described with reference to FIG. 10-1 (i) to 10-16 (i) and 10-1
(O) to 10-16 (o) show 16 input / output channels respectively corresponding to 20 and 22, 21 and 23 in FIG. 10-k
(I) The slot information input to (k = 2 to 16) is output to 10-1 (o) when it is addressed to its own node, and is output to 10-k (o) when it is addressed to another node (exchange). Is done. In this embodiment, the method of erasing the slot information at the receiving node is adopted. In the case of the method of erasing the slot information at the transmitting node, each slot information is duplicated into two, one of which is 10-1 (o) The other is output at 10-k (o). The destination of each slot can be identified by call numbers 40 and 41 described later with reference to FIG. Except for the broadcast information, the transmission slot information input to 10-1 (i) is 10-1 (o) when addressed to the own node, and 10- (0) corresponding to the destination node when addressed to another node. k (o)
Is exchanged and sent. In this embodiment, for example, 10-2 (o) is sent to the LAN node 4 shown in FIG.
10-3 (o) to the LAN node 2 and 10-4 (o) ~
9 (o) to the LAN node 1, that is, 10
−10 (o) to 16 (o) are assigned respectively. From the plurality of output channels, a channel with a low usage rate is selected based on the result of monitoring the slot usage rate. In the case of broadcast information transmission, a broadcast call number described in FIG. At the time of transmission, since a user frame such as a LAN frame has a maximum length of 4 kbytes, it is divided into a user area 44 shown in FIG. 4 and transmitted. Therefore, for example, 10-10 (o) to 16 (o) can be used for the node 1, but
In order to prevent the order of slot information generated from the same user frame from being reversed due to overtaking between slots, output is performed on the same channel as the first slot transmission channel. FIG. 4 shows a transfer slot format in the LAN. The overall format is composed of a header 50 and information 51, and has a total length of 36 bytes. When the call setting information 440 is transferred out of band, the user area 44 indicates the call setting information 440. At the time of data transfer, the call numbers given by the call settings are set to the call numbers 40 and 41. The control information 42 includes call number error detection information, priority information, and the like. Division number 43
Consists of 2 bits for distinguishing the first or middle slot and the last slot in a user frame at the time of slot division, and 6 bits indicating the effective information length bit in the slot. Call control information 440, a protocol identifier 441 indicating a protocol type according to the following format, target call numbers 442 and 443 to be set or released, and a message type 444 indicating a control type such as call setting and release, Additional information 445 and FCS4
Consists of 46. Further, the additional information 445 includes an information element identifier 447, an information element length 448, and information contents 449. FIG. 5 shows a call setup method between nodes and call numbers to be assigned. Each node has a call number group assigned to all other nodes in ascending order of node addresses when the system is set up.
61 to 76 are set by the call setting information 440 in FIG. The out-band control information is realized by broadcast, and the broadcast control call number 77 and the broadcast data call number 78 are set in advance. In this embodiment, since the maximum number of connected nodes is 64, 64 call number groups are assigned to one node including the own node. One call number group is composed of 15 call numbers, which are used as user port numbers. For example, for communication from node 1 to node 1
0) ₁₆ to (000E) ₁₆ call number groups 61 are allocated, and similarly, call number groups 62 to 76 are allocated as shown in FIG. The broadcast number 77 is (00XF) ₁₆ (X = 0 to F),
The broadcast data 78 is (FFXF) ₁₆ (X = 0 to F). FIG. 6 shows functional blocks of the switch 10 of the present embodiment. The slot information is serial-parallel converted by the optical / electrical conversion unit 12 in FIG. 1 and divided into 15 channels by the separation unit 13, and the information portion is input to the data input (D
Connected to I). The header of each slot is connected to the read address terminal (RA) of the relay table 171.
Also, among the data output (DO) of the relay table 171 to which the outgoing line number for the input call number is given at the time of call setting, a new header (the same call number is used for the input and output call numbers) and the busy information are respectively Data input to common buffer 170 (D
I) and the write enable input (WE) via the gate 172, and the outgoing line number is connected to the destination outgoing line number input (DES) of the address pointer 173. The data output (DO) of the empty address FIFO 174 is connected to the data input (DI) of the common buffer 170 and the next data write address input (NWAD) of the address pointer 173, and the empty display output (EPTY) is shared via the gate 172. Buffer 170
Is connected to the write enable input (WE). The write address output (WAD) of the address pointer 173 is connected to the write address input (WA) of the common buffer 170, and the read address output (RAD) is output via the selector 175 to the read address output (RA) of the common buffer 170. ) And the data input of the empty address FIFO 174. The empty cell address register 176 is connected to the selector 175. Next, an operation of writing slot information to the common buffer will be described. The schematic structure of the input slot is shown in FIG.
The detailed structure is shown in FIG. Using the call numbers 40 and 41 in the header 50 as input information, the slot use status and the outgoing line number are obtained from the relay table 171. FIG. 7 (b)
The output of the relay table 171 is shown in FIG. The outgoing line number is input to the address pointer 173, and the common buffer 1
An appropriate write address for writing to 70 is obtained. The write address is given in advance from an empty address FIFO. In the case of an empty slot, no data is written to the common buffer, and the write address is not updated. The data output of the empty address FIFO is stored in the common buffer 170 together with the slot information, whereby the slot information is chained in the common buffer for each identical outgoing line.
Further, this chain is formed for each priority determined by the in-switch priority information 54, and is read out from the high-priority chain in all processes. In the above embodiment, a LAN system in which a plurality of nodes are connected by one transmission line, and a separation unit 13 and a multiplexing unit 14 before and after the four switches 10 are installed in each node has been described. Also, the present invention can be applied to a LAN system in which nodes are connected by a plurality of transmission paths corresponding to input / output ports of a switch. A LAN node and a LAN system according to the present invention include the following embodiments. (1) The switch 10 converts the slot information input from the user equipment interface 11 into the output port 23
Means are provided for forwarding to the output port with the lowest traffic. (2) The switch 10 converts the slot information input from the user device interface 11 into the output port 23
Means are provided for forwarding to an output port predetermined for the destination node. (3) The switch 10 includes means for transferring slot information belonging to the same user (same data frame) input from the user device interface 11 to the same output port. (4) The switch 10 includes means for generating a copy of the broadcast or broadcast slot information input from the user device interface 11 and transferring the copy to a plurality of output ports. (5) The switch 10 exchanges slot information input from the input port in an order according to the priority. (6) The switch 10 gives the slot information input from the user device interface 11 a lower priority than the intra-LAN transfer information received from the transmission line 220, and preferentially gives the intra-LAN transfer information to the output port. And means for transferring. (7) The switch 10 receives the slot information input from the user device interface 11 and the LAN received from the transmission path 220
Priority information is assigned to each slot information during internal transfer, and the switch performs an operation of exchanging slot information to an output port in accordance with these priorities, and deletes the priority information at the time of output. (8) The slot information is transferred in an asynchronous transfer mode (ATM) in broadband ISDN.

【The invention's effect】

According to the present invention, the ring access function unit is provided with a switching function, and it is possible to determine whether the slot information is relayed or received on the node. It is possible to reduce the number to the sum L of the number of connections (LM). Also, the transmission buffer only needs to have the number of user connections, and when (LM) = 1, the hardware amount of the node is 1 / (the number of multiplex rings) as compared with the conventional method.
Can be reduced.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of a LAN node according to the present invention, FIG. 2 is an overall view of a LAN system to which the present invention is applied, FIG.
In FIG. 5, FIG. 6 is a functional block diagram in a node, and FIGS. 7A to 7C are schematic diagrams of a node input slot and a switch, respectively. It is a figure which shows the internal relay table output format and the data structure in a shared buffer. 1 ... upper LAN node, 10 ... channel exchange switch, 11 ...
User device interface, 12 ... optical / electrical converter, 13 ...
LAN frame separation unit, 14 ... frame multiplexing unit, 15 ... electric /
Light conversion unit.

Continuation of front page (72) Inventor Eiichi Amada 1-280 Higashi Koikebo, Kokubunji-shi, Tokyo Inside Central Research Laboratory, Hitachi, Ltd. (56) References JP-A-1-101735 (JP, A) JP-A-63-86635 ( JP, A) JP-A-62-190949 (JP, A) JP-A-61-163753 (JP, A) JP-A-60-65640 (JP, A) IEICE Technical Report (IEICE Technical Report) SE86 −106 “Study of Broadband Subscriber System” Hiroshi Shimizu, Suzutaro Hirosaki IEICE Technical Report (IEICE technical report) IN87-51 “Study of slot access method for backbone LAN” Yoshihiro Taki, et al. Technical report of IEICE (Technical Report of IEICE) CS88-36 “Broadband Optical Subscriber Network: Prototype of Optical Shuttle Bus System” Mitsumi Taniguchi, et al. Technical report of IEICE (Technical Report) IN88-121 "Study of high-speed backbone LAN using ATM technology" Yukiji Yamauchi, Yasuhiro Taki,

Claims (9)

(57) [Claims] 1. A LAN connected to another node device via at least one ring transmission line and communicating with another node by fixed-length slot information including destination information in a header portion.
The node has a plurality of input / output ports of N inputs and L outputs (N and L are integers, N ≦ L), and outputs slot information received from each input port according to destination information included in each header part. Switch means for transferring to a port, means for connecting M (M is an integer, M <N) input and output ports of the switch means to the transmission line, and remaining input / output ports of the switch means A user equipment interface connected to the input port, and among the slot information received from the input port, slot information including destination information corresponding to its own node in a header portion is output to the user equipment interface; A LAN node for transferring information to one of the M output ports. 2. The LAN node according to claim 1, wherein said connection means distributes slot information received from one transmission line to a plurality of input ports, and outputs from a plurality of output ports. Multiplexing means for outputting slot information to one transmission line.
LAN node. 3. The LAN node according to claim 1, wherein said switch means converts the slot information input from said user equipment interface into an output port having the lowest traffic among said M output ports. A LAN node, which selectively transfers data to a LAN node. 4. The LAN node according to claim 1, wherein the switch transfers the slot information input from the user equipment interface to a predetermined output port corresponding to a destination node. A LAN node, characterized in that: 5. The LAN node according to claim 1, wherein the switch transfers a plurality of slot information belonging to the same user frame input from the user equipment interface to the same output port. LAN node characterized by doing. 6. The LAN node according to claim 1 or 2, wherein said switch means operates according to a call number pre-assigned between nodes included in each slot information.
A LAN node for transferring reception slot information from said input port to said output port. 7. In a LAN system comprising a plurality of node devices connected by a transmission line, each of the node devices has a plurality of input / output ports having N inputs and L outputs (N and L are integers, N ≦ L). Switch means for transferring slot information received from each input port to an output port corresponding to destination information included in each header portion; and M (M is an integer, M <N) input ports of the switch means And a means for connecting an output port to the transmission line, and a user equipment interface connected to the remaining input / output ports of the switch means. The user equipment interface transmits slot information addressed to another node device to the user equipment interface. Input to one of the input ports of the switch means via the switch means, and the switch means automatically stores the slot information received from the input port in the header part. Outputting slot information including destination information corresponding to the station node to the user equipment interface, transferring other slot information to any of the M output ports, and outputting slot information output from the M output ports; Is transmitted to the transmission line via the connection means. 8. The apparatus according to claim 7, wherein said plurality of node devices are connected by a plurality of ring-shaped transmission lines corresponding to M input ports and output ports of said switch means. LAN system. 9. The plurality of node devices are connected by one ring-shaped transmission line, and the connection means of each node device transmits slot information received from the transmission line to a plurality of input ports of the switch means. 8. The LAN system according to claim 7, comprising: separating means for distributing; and multiplexing means for outputting slot information output from a plurality of output ports of said switch means to said transmission path.