JPH0373186B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a local network system using a digital communication system. In particular, the present invention relates to a hybrid local network system in which a plurality of node stations are connected through a loop-shaped transmission path, and circuit-switched data communications and packet-switched data communications are transmitted in a time-division manner through a common transmission path.

[Conventional technology]

Loop local area network (hereinafter referred to as
It's called LAN. ) The token method and the time slot access method have been adopted as conventional methods related to loop access control. Further, as a hybrid LAN that combines circuit switching and packet switching, a time slot access method using a time division multiplexing method with a specific frame structure for circuit switching is adopted. In this type of hybrid LAN, each node station is
Loop access control circuit module (common circuit for line switching and packet switching) that has optical/electrical and electrical/optical conversion circuits and time division multiplexing circuits with the optical loop transmission line, and a specific capacity capacity below it. The circuit is constructed by connecting a line switching equipment module and a packet switching equipment module with each other.

However, in this type of hybrid LAN,
The number of circuits required to accommodate circuit switching and packet switching may vary depending on each node station, and this cannot be handled by conventional node stations, which have fixed circuit switching and packet switching circuit capacities. Although this drawback can be compensated for by increasing the number of node stations and increasing the capacity of the node station exchange equipment, this method has the disadvantage of increasing the cost of the system.

That is, as shown in FIG. 2, each node station 1, 2, 3...n of the LAN has a circuit switching device and a packet switching device, and
The central node station 1 particularly has circuit switching time slot allocation management and network system management functions, and is connected to a circuit switching non-packet mode terminal 1a, a packet mode data terminal 1b, and a system monitoring device 1c. The node stations 2, 3...n are connected in series by a high-speed loop transmission line 50 coupled in a loop, and are connected to circuit-switched non-packet mode terminals 2a, 3a,...na such as telephones and data terminals, and packets such as computers. Mode data terminals 2b, 3b, . . . nb are connected. Also, the third
The figure shows the configuration of a conventional node station used in the LAN system shown in Figure 2. This node station 2 includes an optical・The electric signal converter 11 and the electric signal converter 11 that converts the electric signal into an optical signal and sends it to the loop transmission line 50.
An optical signal converter 12 is provided facing the optical signal converter 12, between which the time-division multiplexed high-speed input signal from the loop transmission line 50 is converted into a low-speed line-switched data time-division multiplexed signal and a packet-switched data time-division multiplexed signal. It includes a demultiplexing circuit 13 for demultiplexing, a multiplexing circuit 14 for high-speed multiplexing and outputting time division multiplexed signals, a line switching device 20, and a packet switching device 30.

Here, the number of circuit switching mode processing terminals 2a, packet switching mode processing terminals 2b, etc. accommodated in the circuit switching device 20 and the packet switching device 30 may vary depending on the system conditions used or the environment of each node station. However, in a conventional node station configured with a single line switching device 20 and a single packet switching device 30 having a specific capacity, redundancy is required when applied to a node station accommodating a small number of lines. It has a disadvantage in that it has a complicated hardware configuration and cannot be applied to node stations that require accommodation of large-capacity lines.

[Problem that the invention seeks to solve]

The present invention solves the above-mentioned drawbacks, and can easily respond to requests for increasing/decreasing the types of lines and the number of lines accommodated in each node station of a hybrid LAN, and also allows multiple modules to be configured to respond to each failure. The objective is to provide a LAN that facilitates maintenance in large-scale configurations and system reconfiguration in the event of a failure by providing a disconnection (bypass) function.

[Means for solving problems]

The present invention is a LAN type node station that includes a line switching device, a packet switching device, and a time division multiplexing device. The present invention is characterized by comprising a time division switch inserted between a switching module and a data highway, a packet switching module, and an adapter that cascades the packet switching module and connects it to the data highway.

[Effect]

A circuit switching device and a packet switching device can be constructed by combining the required number of circuit switching modules and packet switching modules. Furthermore, since a logical loop can be formed within a node station by cascade-connecting a plurality of packet switching modules, additional packet modules can be added without changing the core loop.

〔Example〕

DESCRIPTION OF THE PREFERRED EMBODIMENTS A device according to an embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the construction of an embodiment of the apparatus. First, the configuration of this embodiment device will be explained based on FIG. 1. This node station is
Loop multiplexing unit 10N and line switching device 20N
and a packet switching device 30N. Here, the loop multiplexing unit 10N is the optical/electrical switching device 1
1, electrical/optical exchange device 12, and separation circuit 13
, a multiplex circuit 14 , a drop/add circuit 15 , a drop/add data highway 16 , and a time division switch 1
7-1 and 17-2 and packet adapter 1
8-1, 18-2 and 18-3. The line switching device 20N includes a line switching module 21-
1 and 21-2 and packet switching module 3
1-1, 31-2, and 31-3. The loop transmission line 50 is connected to the input of the optical-to-electrical converter 11, and the output of the optical-to-electrical converter 11 is connected to the input of the separation circuit 13. The output of the separation circuit 13 is connected to the first input of the drop/add circuit 15, and the first output of the drop/add circuit 15 is connected to the time division switch 17-1 via the drop/add data highway 16.
17-2 and the input of the packet adapter 18-1. A first output of time division switch 17-1 is connected to a first input of circuit switching module 21-1. A first output of time division switch 17-2 is connected to a first input of circuit switching module 21-2. Line switching module 21-1
A first output of is connected to a second input of time division switch 17-1. Line switching module 21-2
A first output of the time division switch 17-2 is connected to a second input of the time division switch 17-2, and a second output of the time division switch 17-1 and a second output of the time division switch 17-2 are connected to the drop/add data highway 16. It is connected to the second input of the add/drop circuit 15 via the . The first output of the packet adapter 18-1 is connected to the first input of the packet exchange module 31-1,
A first output of packet switching module 31-1 is connected to a second input of packet adapter 18-1. The second output of packet adapter 18-1 is connected to the first input of packet adapter 18-2. The first output of the packet system adapter 18-2 is connected to the first input of the packet switching module 31-2.
-2's first output is the packet adapter 18-2.
is connected to the second input of the packet adapter 1.
The second output of 8-2 is a packet adapter 18-
is connected to the first input of 3. The first output of the packet system adapter 18-3 is connected to the first input of the packet system module 31-3, and the first output of the packet system module 31-3 is connected to the second input of the packet system adapter 18-3. The second output of the packet adapter 18-3 is connected to the second input of the drop/add circuit 15 via the drop/add data highway 16. A second output of add/drop circuit 15 is connected to an input of multiplex circuit 14 . The output of the multiplex circuit 14 is connected to the input of the electrical-to-optical converter 12, and the output of the electrical-to-optical converter 12 is connected to the loop transmission line 50. Further, the circuit switching module 21-1 is connected to transmit and receive data from the circuit switching non-packet mode terminal 2a-1.
The circuit switching module 21-2 is connected to the circuit switching non-packet mode terminal 2a-2 so as to exchange data. Packet exchange module 31-1
is connected to the packet mode data terminal 2b-1 to exchange data, and the packet switching module 31-2 is connected to the packet mode data terminal 2b-2.
It is connected to send and receive data. The packet switching module 31-3 is connected to the packet mode terminal 2b-3 so as to exchange data.

Next, the operation of this embodiment device will be explained based on FIG.

In the loop multiplexing unit 10N, the demultiplexing circuit 13 and the multiplexing circuit 14 are connected by a drop/add circuit 15, and branch data from the drop/add circuit 15 is accommodated in this node station via a drop/add data highway 16. is sent to exchange modules 21 and 31. The circuit switching module 21 is
They are connected via a time division switch 17, and transmission and reception are performed using corresponding channels on time division multiplexed data. The insertion data to the drop/add circuit 15 is inputted via the drop/add data highway 16 onto a corresponding channel in accordance with the insertion request signal. The output and insertion request signal from the time division switch 17 and the packet adapter 18 to the drop/add data highway are open collector outputs. The packet switching module 31 is connected to the branch/insert data highway 16 via the packet adapter 18, receives packet branch data from the first adapter 18-1 forming the logic loop, and branches the transmitted data directly from this adapter. It is not output to insert data 16, and the next adapter 1
8-2, and from the final adapter 18-3,
Transmission output data is branch/insertion data highway 16
is output to. This packet adapter 18-
1, 18-2 and 18-3, packet switching module 31 is bypassed within this adapter in accordance with bypass requests from packet switching modules 31-1, 31-2 and 31-3. These packet adapters 8-1, 18-2 and 18
-3 and time division switches 17-1 and 17-
2 are exchange modules 21-1, 21-2, 31-1, 3 accommodated in this node station.
1-2 and 31-3.

〔Effect of the invention〕

As explained above, the present invention allows each node station to combine the required number of circuit switching modules and packet switching modules, so that the optimal scale of circuit switching function and packet switching function required for each node station can be achieved. It is possible to configure a node station with

Furthermore, since each packet switching module in the node station adopts a logical loop configuration, adding more packet switching modules does not simply increase the number of accommodated lines, but also has the effect of increasing the processing capacity as a sum of the modules. There is.

Further, since the connection adapter for the packet switching module has a bypass function in response to a failure or a disconnection request for each packet switching module, it is effective in facilitating maintenance and reconfiguration in the event of a system failure even when the system is scaled up.

[Brief explanation of drawings]

FIG. 1 is a block configuration diagram showing the configuration of an apparatus according to an embodiment of the present invention. FIG. 2 is a block configuration diagram showing the configuration of a local area network system. FIG. 3 is a block configuration diagram showing the configuration of a conventional device. 1... Central node station, 2, 3
...n...Node station, 1a, 2a, 3
a,...na...Line-switched non-packet mode terminal,
1b, 2b, 3b,...nb...Packet mode data terminal, 1c...System monitoring device, 10,1
0N...Loop multiplexing unit, 11...Optical/electrical converter, 12...Electrical/optical converter, 13...Separator circuit, 14...Multiple circuit, 15...Add/drop circuit, 16...Add/drop circuit Data Highway, 17...
...Time division switch, 18...Packet system adapter, 20, 20N...Line switching device, 21...Line switching module, 30, 30N...Packet switching device, 31...Packet switching module, 50
...Loop transmission line.

Claims (1)

[Claims] 1. A local area network system comprising: (1) a circuit switching device, a packet switching device, and a time division multiplexing/demultiplexing device for coupling the circuit switching device and the packet switching device to a loop-shaped digital transmission path. The node station includes a data highway that connects the time division multiplexing/demultiplexing device and the line switching device, and also connects the time division multiplexing/demultiplexing device and the packet switching device; A time division switch is inserted between the circuit switching module and the data highway, and the packet switching device includes an arbitrary number of packet switching modules, and each packet switching module is provided with an adapter through which the input and output signals of each packet switching module pass, and this adapter connects the input to the output of the previous adapter and the output to the input of the next adapter, thereby allowing the above packet switching module to pass through. The exchange modules are connected in cascade, the input of the connected first-stage adapter and the output of the last-stage adapter are connected to the data highway, and the plurality of packet exchange modules connected in cascade are connected to the data highway. A local area network type node station characterized by a logical loop formed within the node station.