JPH04129348A - Data switch system - Google Patents

Abstract

PURPOSE:To minimize the transmission delay of a path and to almost eliminate a difference of a transmission delay between transmission and reception by using a primary path and a secondary path simultaneously in the usual communication state. CONSTITUTION:An ADM ring having optional number of nodes A, B - is formed on a ring transmission line comprising a primary path P and a secondary path S sending a signal in different directions. Furthermore, each node is provided with a branch means 1 at the sender side to send a signal to both the primary path P and the secondary path S. On the other hand, a changeover means 2 is provided to a receiver and either the primary path P or the secondary path S which has a smaller transmission delay time is selected to receive the signal.

Description

[Detailed Description of the Invention] [Summary] By using both the data switch type primary bus and secondary bus in an ADM ring configuration, transmission delay is minimized and the transmission delay difference between transmission and reception is minimized. Each node in an ADM ring configuration has an arbitrary number of nodes on a ring-shaped transmission path consisting of a primary bus and a secondary bus that transmit signals in different directions. , the sending side is equipped with branching means for sending signals to both the primary bus and the secondary bus, and switching is made to select the one with the shorter transmission delay time between the primary bus and the secondary bus to receive the signal. It is configured by providing means on the receiving side.

[Industrial application field]

The present invention is a two-fiber ADM (Add/D
The present invention relates to a data switching system in a ring configuration, particularly in a two-fiber ADM ring configuration, which minimizes transmission delay and almost eliminates the difference in delay between transmission and reception.

A two-fiber ADM ring configuration uses a dual-configuration transmission path consisting of a primary bus and a secondary bus constructed of optical fibers to form a large-capacity ring-shaped multiplexed communication path that connects each region. , an arbitrary number of nodes provided on this communication path perform communication between nodes by adding or removing transmission signals.

In such an ADM ring configuration, it is desired to minimize the transmission delay between each node and to almost eliminate the difference in transmission delay between transmission and reception.

[Conventional technology]

The conventional way of thinking about ADM ring configuration is to use a primary bus in normal times, and as a backup,
The idea was to use the secondary bus in the event of a failure.

FIG. 4 explains a conventional ADM ring configuration, in which P indicates a primary bus and S indicates a secondary bus, each forming a ring and transmitting optical signals in opposite directions as shown in the figure. It is something that is transmitted. Nodes A, B, etc. are provided on the ring, and each node is configured to be able to insert and extract signals.

In the configuration shown in Fig. 4, primary bus P is used for normal communication, so for example, communication between adjacent nodes A and B is A-+B force direction communication, which has a short distance and transmission delay. few. On the other hand, communication in the B→A direction involves a long detour, so the distance is long and the transmission delay is large.

[Problem to be solved by the invention]

When using this type of communication, if the number of nodes increases or if there is an extremely long bus, the transmission delay may become significantly longer, and the transmission and reception may be delayed. There is a disadvantage that the difference in transmission delay may be large.

The present invention aims to solve the problems of the prior art, and minimizes transmission delay by using both a primary bus and a secondary bus even in normal communication. The purpose of this invention is to provide a method that can minimize the difference in transmission delay between transmission and reception.

[Means to solve the problem]

As shown in FIG. 1, the basic configuration of the present invention is such that an arbitrary number of nodes A, B, - In each node in an ADM ring configuration having The signal is received by selecting the one with the shorter transmission delay time between the bus P and the secondary bus S.

Further, the present invention provides an arbitrary number of nodes A on a ring-shaped transmission path consisting of a primary bus P and a secondary bus S that transmit signals in different directions.

In each node in the ADM ring configuration having B, -, branching means 1 is provided on the transmitting side to send signals to both the primary path P and the secondary path S, and switching means 2 is provided on the receiving side, A signal from either the primary path P or the secondary path S is selected and received, and a switching trigger is sent from the transmitting side to the primary path P or the secondary path when the node is started up or when a failure in the node is restored. At the same time, the switching means 2' is controlled to select the one with the shorter transmission delay time of this switching trigger between the primary path P and the secondary path S. It is designed to perform reception.

[Effect]

In the present invention, in each node in an ADM ring configuration having an arbitrary number of nodes on a ring-shaped transmission path consisting of a primary path and a secondary path that transmit signals in different directions, the primary path and the secondary path are connected on the transmitting side. - A signal is sent to both the primary path and the secondary path, and the receiving side selects the one with the smallest transmission delay time between the primary path and the secondary path to receive the signal.

FIG. 2 explains the path setting in the method of the present invention, and in the direction from node A to node B,
In the primary path P, the path with the minimum transmission delay time (shortest distance) between node A and node B is set, and in the direction from node B to node A, the path between node B and node A is set in the secondary path S. It is shown that the path with the minimum transmission delay time (shortest distance) is set.

Further, in the present invention, in each node in an ADM ring configuration having an arbitrary number of nodes on a ring-shaped transmission path consisting of a primary path and a secondary path that transmit signals in different directions, the primary path and A signal is sent to both the secondary path and the primary path by switching means on the receiving side.
Either the signal on the primary path or the secondary path is selected and received. In this case, when starting up a node or recovering from a failure in the node, a switching trigger is sent from the transmitting side to the primary path or secondary path. At the same time, the switching means is controlled to select the one with the shorter transmission delay time of this switching etriger between the primary path and the secondary path, so that reception in the normal state is performed thereafter. Therefore, in a normal state, a path with the minimum transmission delay time (shortest distance) between nodes is set in the direction from one node to another node and in the opposite direction.

〔Example〕

FIG. 3 shows an embodiment of the present invention.
An example of the configuration of a node in an M-ring configuration is shown, and a circuit configuration for coupling a signal inserted from the node and a signal extracted at the node to each path is illustrated.

In FIG. 3, reference numeral 11 denotes a branch circuit, which branches the insertion signal at the node sent from the low-order group interface of the node in both directions, and sends it to a multiplexing circuit (
MUX) 12. Input to 13. Multiplexing circuit 12.13
, the insertion signal is multiplexed with other signals, converted into an optical signal via an electrical/optical conversion circuit (E/○) 14.15, and transmitted to the primary path P and secondary path S.

On the other hand, the received signals from the primary path P and the secondary path S are transmitted to the optical/electrical conversion circuit (0/E) 16, respectively.
．． 17, it is converted into an electrical signal, and sent to a separation circuit (DMUX).
) 18 and 19 to separate the desired channels. The data switch 20 selects a signal to be extracted at that node from the signals separated by the separation circuits 18 and 19, and takes it into the low-order group interface.

The selection of data switch 20 in the circuit of FIG. 3 is controlled as follows.

(1) Control at node startup When power is turned on in each device in the node, a power-on trigger is sent from the power-on reset circuit 21. The power-on trigger passes through an OR circuit (OR) 22, is multiplexed into bus data via a multiplexing circuit 12.13, and is sent to the primary bus P and secondary bus S as a switching trigger. Multiplexing of switching triggers is performed, for example, by inserting them into the bus overhead of an empty channel.

The receiving node receives this switching trigger from both directions of the primary bus P and the secondary bus S, and extracts the switching trigger in the separation circuit 18.19.

This switching trigger is applied to the data switch 20 via OR circuits (OR) 23 and 24, but at this time, by determining the arrival time of both signals, the data switch 20 selects which one the switching trigger arrived first. The switching is performed to select the bus.

By performing such an operation, a selection is made between the transmitting node and the receiving node so as to mutually receive data on the bus with the smaller transmission delay.

(2) When a node recovers from an input failure, etc. When a failure such as a fiber break occurs in a node, a bus AIS signal is output from the separation circuit as a failure occurrence notification, and the data switch 20 receives this signal via an OR circuit. Now, select the bus that has no fault and receive only the signals from this bus from now on.

When the fault is restored, the node sends out a fault recovery signal from the multiplexing circuit on the restored side.

The node that receives this sends out a failure recovery confirmation signal from the separation circuit. This signal is passed through the OR circuit 22, and as a switching trigger, is passed through the multiplexing circuits 12 and 13 to the primary
It is transmitted in both directions, bus P and secondary bus S.

At the receiving node, the switching trigger is extracted in the separation circuit 18.19 and applied to the data switch 20 via the OR circuit 23.24, so that the data switch 20 selects the bus on which the switching trigger arrived first. A switch is made.

As a result, between a short distance bus formed between the sending node and the receiving node and a long distance bus in the opposite direction, data is automatically selected to receive data from the bus with the least transmission delay. be exposed.

〔Effect of the invention〕

As explained above, according to the present invention, when transmitting and receiving data in an ADM ring configuration, bus transmission delays are minimized by simultaneously using the primary bus and the secondary bus in normal communication conditions. At the same time, it becomes possible to almost eliminate the difference in transmission delay between transmission and reception.

[Brief explanation of drawings]

Fig. 1 is a diagram showing the basic configuration of the present invention, Fig. 2(a),
(b) is a diagram explaining the present invention in detail, FIG. 3 is a diagram showing one embodiment of the present invention, and FIGS. 4(a) and (b) are diagrams explaining the conventional ADM ring configuration. P is the primary bus, S is the secondary bus, and A. B. is a node, 1 is a branching means, and 2゜2' is a switching means.

Claims (2)

[Claims] (1) ADM ring configuration with an arbitrary number of nodes (A, B,...) on a ring-shaped transmission path consisting of a primary path (P) and a secondary path (S) that transmit signals in different directions. In each node, a branching means (1) for sending signals to both the primary path (P) and the secondary path (S) is provided on the transmitting side, and the branching means (1) for sending signals to both the primary path (P) and the secondary path (S) is provided, and the transmission delay time is selected from the primary path and the secondary path, whichever has the shorter transmission delay time. A data switching system characterized in that a receiving side is provided with switching means (2) for selectively receiving signals. (2) ADM ring configuration with an arbitrary number of nodes (A, B, ...) on a ring-shaped transmission path consisting of a primary path (P) and a secondary path (S) that transmit signals in different directions. Each node in the transmission side is equipped with a branching means (1) for sending signals to both the primary path (P) and the secondary path (S), and the transmission side is equipped with branching means (1) for sending signals to both the primary path (P) and the secondary path (S).
The receiving side is equipped with a switching means (2') that selects and receives one of the signals of S), and the switching trigger is sent from the transmitting side to the primary path (P) when starting up a node and when recovering from a failure in the node.
and the secondary path (S), and
The switching means (2') is controlled to select whichever of the primary path (P) and the secondary path (S) has a shorter transmission delay time of the switching trigger, so that reception in the normal state is performed thereafter. The data switch method is characterized by: