JPH01206755A - Node device - Google Patents

Abstract

PURPOSE:To erase a packet, which is transmitting from its own node, without fail by erasing the received packet until the number of transmitting packets and the number of receiving packets are coincident. CONSTITUTION:A node device 100 has a media access control(MAC) sub-player 101 to support the system of an LAN, an FDDI-MAC sub-player 102 to support the FDDI system of the LAN and a repeating part 103 which is an interface to absorb the difference of the systems between these sub-players. Until the number of the packets to be transmitted in a condition that a transmitting right is obtained and the number of the packets to be received after this transmission is started are coincident, this node device 100 does not repeat but erases the packet, which is received after the transmission is started, to the next node.

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention is directed to FDD I (Fiber Dist
The present invention relates to a node device that is applied to a token ring LAN (o-cal area network) based on the Ributed Data Interface.

[Conventional technology]

The FDDI type token ring LAN is based on the American ANSI
/X3T9.5 Standardization is being promoted by the committee 1 0
LA assuming the use of oMp b S optical fiber
N has the following characteristics.

A plurality of nodes are connected in a ring shape through a transmission path through which frames, which are packetized information, are transmitted in one direction. The node that holds the token transmitted through this transmission path has the right to transmit on the transmission path. When it finishes transmitting the frame, it transmits a token and relinquishes the right to transmit. Further, if the source address of the received frame matches the address of the node itself, the frame is deleted without being relayed to the next node.

[Problem to be solved by the invention]

By the way, in recent years, there are cases where a plurality of networks are connected, and in such cases, if the method described in 2 is used as is, the following problems will occur.

In other words, when a frame arriving from another network is relayed to the FDD, 1 type LAN, the source address of this frame is the address of the node in the other network, so the node that relayed the frame Even if the frame returns after going around the ring-shaped transmission path, it cannot be determined that the frame was sent by the own node. Therefore, when joining networks,
It was not possible to use the FDDI I method as is.

Therefore, the present invention is capable of accurately relaying and transmitting packets from one network to another network when a plurality of networks are combined.
The object of the present invention is to provide a node device that can operate without any problems as a node of a LAN using a conventional method.

[Failure to solve the problem]

In the notebook device according to the present invention, a plurality of nodes are connected in a ring shape by a transmission path through which packetized information is transmitted in one direction, and a node holding a 1-kun transmitted through the transmission path or A node device of the 1-Kun method LAN that has the transmission right on the path and sends 1-Kun when it finishes transmitting a packet, and the number of packets transmitted with the transmission right obtained and the start of this transmission. The present invention is characterized in that it includes an erasing means that erases packets received after the start of transmission without relaying them to the next node until the number of packets received later matches the number of packets received later.

[Effect]

Since the node device according to the present invention is configured as described above, the control of transmission rights and the control of packet transmission are the same as those of the FDDI system, so it can function as a node of a LAN of the FDDI system, and moreover, it can be accessed from its own node. Since the erasure of transmitted packets is controlled by matching the number of transmitted packets with the number of received packets, it can be performed accurately and
Performs relay transmission without failure as a connection node with a DDI-B-type LAN.

〔Example〕

DESCRIPTION OF THE PREFERRED EMBODIMENTS A node device according to an embodiment of the present invention will be described below with reference to FIGS. 1 and 2 of the accompanying drawings.

FIG. 1 is a block diagram of a node device 100 according to an embodiment of the present invention, and FIG. 2 is a block diagram of a composite LAN to which the node device]00 is applied.

The node device 100 connects the node 2 .
2. FDD1 type LA in which ,... are connected in a ring shape
Configure one node of N200 and connect other LA
Configure the N300 node.

Whether the other LAN 300 is an FDDI LAN or another LAN, the node device]00
Since the LAN 200 has a function of absorbing the difference in specifications from the LAN 200 of the FDDI I method, no particular problem will occur. Node 2 performs transmission using the FDDI method.

The node device 100 is a MAC (media access control) layer 1 that supports the LAN 300 method.
01 and the FDD I-MAC sublayer (hereinafter referred to as FDD I-M
It's called AC. )] 02, and a relay unit 103 which is an interface that absorbs the differences in methods between these layers. In addition to these, each L
Corresponding to the AN system, unillustrated configurations such as a layer above the logical link control sublayer, a physical layer, an interface connector, a main line coupling unit, etc. are included, but since they are not directly related to the present invention, their explanation will be omitted. .

FDDI-MAC1,02 is equipped with a counter 104, which operates as follows. When a frame is transmitted from the LAN 300 and given via MACl, 01 and relay unit 103, FDD I-MACl, 02 is 1.
・-Kun is held and frames can be transmitted. At this time, the FDD I-MAC 102
Every time a frame is given from 03 onwards, the counter 1.04 is incremented by 1. Furthermore, when the frame can be transmitted while holding 1.-kun, the FDD I-MAC 102 refers to the counter 104 when receiving a frame from the node of the LAN 200, and when the value is greater than or equal to "1", the is decremented by "1", the received frame is deleted without being relayed to the next node of the LAN 200, and when the value of the counter 104 is "0", the received frame is relayed to the next node of the LAN 200 (the first (route indicated by a in Figure 1). Also,
When the value of the counter 104 is other than "0" and a token is received, the value of the counter 104 is reset to "0",
Transition to frame relaying operation.

Since the relay of frames from the LAN 200 to the LAN 300 is not directly related to the present invention, it is shown by a broken line in FIG. 1 and its explanation will be omitted. This node device 100 relays between the LAN 300 and the LAN 200, and it is assumed that no separate data transmission request is issued from its own node.

The node device 100 configured in this manner operates as follows. When the frames transmitted from the LAN 300 are accumulated in the relay unit 103 (at this stage, the frames are assumed to conform to the FDDI system).
A data transmission request is given to FDD I-MAC 102. As a result, the FDD I-MAC 102 starts receiving usable tokens, captures and holds the usable tokens, and obtains the right to transmit on the LAN 200. Next, the FDD I-MAC 102 receives the frame from the relay unit 10B, increments the value of the counter 04 by "1", and transmits the same frame to the next node 2□ of the LAN 200. At the same time, the FDD I-MAC 102 is receiving a frame transmitted from a node on the LAN 200, and when a frame is received, unless the value of the counter 04 is "0", the value is decremented by "1". At the same time, the process of erasing the received frame is started.

On the other hand, the other node 2.2□ of the LAN 200.

... is a relay that sends a frame to the next node upon receiving it (the destination address is the same as the address of the own node ---
7 - Make copies if necessary. ), but at the same time, if a frame containing the same source address as the own node's address is received, it will be erased, so after the node device 100 captures the token, the node device 100
The frame that first arrives at 0 is the frame transmitted from the node device 100. Therefore, FDDI-MA
When the number of frames for which the C 102 increments the value of the counter 104 is received, this node device 1
When the reception of the frame transmitted from 00 is completed, the counter 1
The value of 04 is "0". From now on, FDD I-M
The AC 102 will start relaying the frame within the LAN 200.

Prior to this, the FDDI-MAC 102 transmits a token when there are no more frames to transmit.

Thus, the frame transmitted from LAN 300 is F
The data will be accurately transmitted within the DDI LAN 200. In addition, FDD I-MAC102 has counter 1
When the value of 04 is other than "0", when a token is received, the value of the counter 104 is set to "0" and the process returns to the above-mentioned relay operation, so that stable operation of the system can be achieved.

The present invention is not limited to the above embodiments, and various modifications are possible.

For example, the frames transmitted by the node device may include not only those transmitted from other LANs, but also frames obtained from a terminal that generates a data transmission request provided at the node device. Further, in the embodiment, the node device is used for relay connection between LANs, but it is also possible to apply it to a node of an FDDI type LAN.

〔Effect of the invention〕

As explained in detail above, in the present invention, received packets are deleted until the number of transmitted packets and received packets match, so packets transmitted from the own node can be accurately deleted, and multiple networks can be connected. In this case, it is possible to accurately transmit packets from one network to the other network (FDDI system), and it is possible to operate as a node of an FDDI system LAN without any problems. Moreover, since the configuration is simple and the process of identifying frames to be erased does not take much time, it is possible to
This is convenient for the DDI method.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of a node device according to the present invention, and FIG. 2 is a block diagram of a composite LAN to which the node device according to the present invention is applied. 1... Optical fiber, 2.2... Node, 100...
... Node device, 10] ... MAC sublayer, 10
2...MAC sublayer of FDDI method, 103...
Relay section, 104...Counter, 200...FDD
I-type LAN, 300...LAN0 patent applicant Sumitomo Electric Industries Co., Ltd. Patent attorney Yoshiki Hase 300
200 Example configuration Fig. 1

Claims (1)

[Claims] A plurality of nodes are connected in a ring shape by a transmission path through which packetized information is transmitted in one direction, and a node holding a token transmitted through the transmission path has the right to transmit on the transmission path. In a token-based LAN node device that has a LAN and sends a token when it finishes transmitting a packet, the node device in the token-based LAN sends a token when it finishes transmitting a packet. 1. A node device comprising erasing means for erasing a packet received after starting transmission without relaying it to the next node.