JPH0144061B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of the Invention) The present invention relates to a repeater capable of coupling optical star couplers in a tree shape.

(Prior art) Figure 1 shows a conventional optical star coupler repeater (patent application 1983) that connects optical star couplers in a tree shape.
-216963 "Optical repeater for optical star coupler"), 1 is a repeater for optical star coupler, 2 and 3 are optical/electrical conversion circuits, and 4 and 5 are electrical/optical conversion circuits. , 6 is an optical input detection circuit, 7 is an inverter circuit, 8 is an OR circuit, 9 is a collision detection circuit,
10 is a gate circuit, 11 is an output terminal to the input optical fiber of the optical star coupler, 12 is an input terminal from the output optical fiber of the optical star coupler, 13 is an output terminal to the coupling relay node optical fiber, and 14 is an output terminal to the optical star coupler. This is an input terminal from a branching relay node optical fiber.

The operation of this repeater is to convert an optical signal input to the input terminal 14 from the branching relay node optical fiber into an electrical signal in the optical-to-electrical conversion circuit 2 and amplify it, and the output is sent to the electrical-to-optical conversion circuit 4. The signal is converted into an optical signal and output to the output terminal 11 to the input optical fiber of the optical star coupler. On the other hand, the output of the optical/electrical conversion circuit 2 enters the optical input detection circuit 6, and further passes through an inverter circuit 7 and an OR circuit 8 to control a gate circuit 10. This control is performed so that the gate circuit is opened when there is no optical input to the input terminal 14 from the branching relay node optical fiber.

The optical signal input to the input terminal 12 from the output optical fiber of the optical star coupler is converted into an electric signal and amplified by the optical-to-electrical conversion circuit 3, one of which is input to the gate circuit 10, and the other is input to the collision detection circuit 9. When a collision of optical input is detected, a gate circuit 10 is opened through an OR circuit 8. The output of the gate circuit 10 is converted by the electrical/optical conversion circuit 5 and output to the output terminal 13 to the coupling relay node optical fiber. (In addition, the circuit example of the collision detection circuit 9 is
−136574 “Signal Collision Detection Method”. ) Figure 2 shows a communication network using the repeaters shown in Figure 1, where 1-1 to 1-5 are repeaters for optical star couplers, 15-1 to 15-6 are input optical fibers,
6-1 to 16-6 are output optical fibers, 17-1 to
17-6 is a coupling relay node optical fiber, 18-
1 to 18-6 are branching relay node optical fibers, 1
9-1 to 19-6 are optical star couplers with relay nodes, and 20-1 to 20-17 are terminals.

This includes 5 repeaters for optical star couplers (1
-1 to 1-5), a total of 17 terminals 20-1
An example of communication between arbitrary terminals 20-17 is shown.

In communication between the terminals, an optical signal transmitted from the terminal 20-7 passes from the input optical fiber 15-3 to the optical star coupler 19-3 with a relay node, and reaches the terminal 20-8, allowing communication.

In this case, optical star coupler 1 with relay node
The optical signal entering 9-3 is sent from the branching relay node optical fiber 18-3 to the optical star coupler repeater 1-
It also goes into 2. The optical signal that enters this repeater 1-2 is amplified and enters the next optical star coupler 19-2, and is transmitted to the terminals 20-4 to 20-2 connected thereto.
Can communicate with -6. By repeating this process, it is possible to communicate with all the terminals 20-i, and a part of the optical signal is sent to the repeater 1 through the output optical fiber 16-2.
It comes back to -2. When this returned optical signal is amplified and input to the optical star coupler 19-3, it collides with the original light, so the gate circuit 1 shown in FIG.
Setting it to 0 prevents it from returning. This gate circuit 10 is
When there is optical input from the branching relay node optical fiber 18-3, it functions to close the gate. However, if the light returning from the optical star coupler 19-2 has already collided (this can be detected due to an abnormality in the received light level or a violation of the code conversion rules of the received light signal), the gate is unconditionally opened and the collision has occurred. Terminals 20-7 and 20- connected to Hikari Star Coupler 19-3
Let 8 know. In addition, terminals 20-7 and 20-8
Optical signals transmitted from other sources and normally received by the repeater 1-2 are sent to the coupling relay node optical fiber 17-2.
3. Pass through Hikari Star Katsupura 19-3 and terminal 20-
7 and 20-8. If this signal returns to the repeater 1-2 via the branching relay node optical fiber 18-3 again, a signal collision will occur.
Therefore, it is necessary that the optical star coupler 19-i used has no optical path between the coupling and branching relay nodes 17 and 18.

In this way, since the optical star coupler repeater 1 has these functions, any terminal 20-
The optical signal emitted from i will be sent to all terminals. Furthermore, if that optical signal collides with an optical signal emitted from another terminal, the collided optical signal will reach the transmitting terminal, indicating that there has been a collision.

From the above, it can be seen that communication is possible between any terminals shown in FIG. Also, by returning the collided signal, packet transmission is possible using CSMA/CD (Carrier Sense Multiple Access Procedure with Collision Detection).

However, in order to connect optical star couplers using this repeater, star couplers with relay nodes for branching and coupling that do not couple with each other are required. This had the disadvantage that this repeater could not be used if a normal optical star coupler, in which input and output optical fibers were attached to both ends of a simple mixing waveguide, was used.

(Object of the Invention) The present invention provides an optical transmission wavelength λ _R of the coupling output of a repeater.
is different from the optical transmission wavelength λ _T of the terminal (node) and is a wavelength that can be received by the terminal (node), and a filter is inserted to remove the optical transmission wavelength λ _R before the optical receiver at the branching input of the repeater. Its purpose is to construct a communication network using conventional optical star couplers.

(Structure and operation of the invention) The present invention connects optical star couplers in a tree shape, and constantly performs a relay operation from the branch side to the trunk side.
The relay operation from the trunk side to the branch side is performed only when there is an abnormality in the signal from the trunk side or when there is no signal from the branch side. Use a light source that outputs a wavelength different from the light source wavelength of the connected equipment and a wavelength that can be received by that equipment, and remove the light source wavelength component of the branch side of the repeater from the branch side receiver, It also has a filter circuit that passes the light source wavelength component of the devices connected to the optical star coupler on the branch side, and the light emitter and receiver on the main side can communicate with the devices connected to the optical star coupler on the main side. It uses a wavelength of

FIG. 3 is a block diagram showing the configuration of an embodiment of the present invention, in which 21 is a repeater for the optical star coupler of the present invention, 22 is a filter for removing wavelength λ _R , 11 and 23
are the output terminals to the input optical fibers of the optical star couplers on the main side and branch side of the tree-shaped communication network, respectively,
12 and 24 are input terminals from the output optical fibers of the optical star couplers on the main side and branch side of the tree-like communication network, respectively, and the other symbols are the same as those shown in FIG.

The optical star coupler repeater 21 of the present invention is
To incorporate it into the communication network shown in the figure, you can do as follows. That is, first, the optical star coupler 19-i (i=1, 2, . . . , 6) with a relay node is changed to a normal optical star coupler 19'-i. As a result, the coupling relay node optical fiber 17-i in FIG.
Also, branch relay node optical fiber 1
8-i is any one of the output optical fibers 16 connected to the optical star coupler 19'-i. Here, for example, optical star coupler repeater 1-
The output terminal 11 on the trunk side of 2 is connected to the input optical fiber 15-2 to the optical star coupler on the trunk side, and the input terminal 12 on the trunk side is connected to the output optical fiber 16-2 of the optical star coupler on the trunk side. Connecting. In addition, the branch-side output terminal 23 of the optical star coupler repeater is connected to the input optical fiber 17-3 to the branch-side optical star coupler, and the branch-side input terminal 24 is connected to the branch-side optical star coupler. The output optical fiber 18-3 is connected to the output optical fiber 18-3.

The following optical star coupler repeater 1-1, 1-
By connecting 3, 1-4 and 1-5 in the same manner, the optical star coupler repeater 21 according to the present invention can be incorporated into FIG.

The operation of the communication network using this repeater 21 is the same as that shown in the description of the conventional technology, so the description will be omitted.

Next, the branching and coupling relay nodes that do not couple to each other are made equivalent by changing the repeater 1 using a conventional optical star coupler (a coupler in which all the light that enters the input node is output to the output node). We show that it can be realized in a practical manner.

The characteristics required for the branching and coupling relay node optical fibers 18 and 17 of the optical star coupler are as follows:
It is sufficient that the light entering the coupling relay node optical fiber 17 is not output to the branching relay node optical fiber 18 but is output to the other output optical fibers 16.
Therefore, the optical wavelength input to the coupling relay node optical fiber 17 is set to be different from the wavelength λ _T used by the terminal 20, and to be a wavelength λ _R that can be received by the terminal 20 connected to another node. (λ _R ≠ λ _T ). Furthermore, if a wavelength λ _R removal filtering circuit 22 is inserted into the input of the optical star coupler repeater 21 of the branching relay node optical fiber 18, the signal from the terminal 20 can be received. The signal output from the repeater 21 can be removed.

(Effects) As explained above, the present invention uses a tree-like network as a light source for a branch repeater using a wavelength different from that used in other terminals, and filters the receiver to remove the light source wavelength. Although a circuit is required, the advantage is that a tree-shaped communication network can be constructed using conventional optical star couplers.

[Brief explanation of drawings]

Figure 1 is a diagram showing the configuration of a conventional optical star coupler repeater, Figure 2 is a diagram showing the configuration of a tree-shaped communication network using the repeater shown in Figure 1, and Figure 3 is a diagram showing the configuration of a conventional optical star coupler repeater. 1 is a block diagram showing the configuration of an embodiment of an optical star coupler repeater according to the invention; FIG. 1, 1-1 to 1-5, 21... optical star coupler repeater, 2, 3... optical/electric conversion circuit, 4,
5... Electrical/optical conversion circuit, 6... Optical input detection circuit, 7... Inverter circuit, 8... OR circuit, 9
... Collision detection circuit, 10 ... Gate circuit, 11,
23... Output terminal to the input optical fiber of the optical star coupler, 12, 24... Input terminal from the output optical fiber of the optical star coupler, 13... Output terminal to the coupling relay node optical fiber, 14... ...Input terminal from branch relay node optical fiber, 15,
15-1 to 15-6...input optical fiber, 16,
16-1 to 16-6...output optical fiber, 17,
17-1 to 17-6... Relay node optical fibers for coupling, 18, 18-1 to 18-6... Relay node optical fibers for branching, 19, 19-1 to 19-6...
...Optical star coupler with relay node, 20,20
-1 to 20-17...Terminal, 22...Wavelength λ _R removal filter.

Claims (1)

[Claims] 1 The optical star couplers are connected in a tree shape, and the relay operation from the branch side to the trunk side is always performed.The relay operation from the trunk side to the branch side is performed only when the signal from the trunk side is abnormal or when the signal from the branch side is abnormal. In a repeater that operates only when there is no signal, the branch side light emitter outputs a wavelength that is different from the light source wavelength of the equipment connected to the branch side optical star coupler and that is receivable by that equipment. A light source is used, and the light receiver on the branch side has a filtering circuit that removes the light source wavelength component of the branch side of the repeater and passes the light source wavelength component of the devices connected to the branch side optical star coupler, 1. A repeater for an optical star coupler, characterized in that a light emitter and a light receiver on the main side use a wavelength that allows communication with devices connected to the optical star coupler on the main side.