JPH08251103A - Optical communication system - Google Patents

Abstract

PURPOSE: To provide an optical communication system which can prevent the occurrence of an optical surge owing to misoperation at the time of connecting an optical connector. CONSTITUTION: The optical communication system is provided with a transmission line 13 to which pilot signal light is always supplied and an optical transmitter 11 having a function for discriminating the connection state of the transmission line 13 by judging whether pilot signal light from the transmission line 13 is inputted or not through an optical connector 12 and starting the transmission of main signal light while a level is increased with a prescribed time constant (time constant by which the optical surge does not occur).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication system, and more particularly to an optical communication system in which a transmission line and an optical transmitter are connected via an optical connector.

[0002]

2. Description of the Related Art In an optical communication system, as shown in FIG. 2, the output of an optical transmitter 11 is generally introduced into a transmission line 13 via an optical connector 12. The transmission line 13 is provided with an optical amplification repeater or an optical receiver that amplifies an optical signal, but these devices perform control such as maintaining a constant level of the optical signal, and therefore, are instantaneous. If a large amount of light is input, a so-called optical surge may occur, causing an abnormality in the circuit that constitutes the device. Therefore, when the open optical connector 12 is connected, the optical output of the optical transmitter 11 is stopped by, for example, disconnecting the main signal input to the optical transmitter 11.
After making the optical connector connection, it was necessary to start the optical transmitter 11.

[0003]

As described above, the conventional optical transmitter requires an operation for preventing an optical surge when the optical connector is connected, and if the operation is erroneous, the circuits constituting the system will be affected. There is a problem that a failure occurs, and there is a demand for a system that can reliably prevent the occurrence of an optical surge without performing any special operation.

For this purpose, it is necessary for the optical transmitter to automatically determine whether or not the optical connector is connected in some way.
As a technique for determining whether or not an optical connector is connected, for example, the technique shown in FIG. 3 is known.

This figure shows an outline of the "optical laser output device" disclosed in Japanese Patent Laid-Open No. 3-276781. As shown in the figure, this optical laser output device is a laser light source. 31, directional coupler 32, and optical connector 3
3 and a detector 34, the optical laser output device is used in a state of being connected to the optical connector 35 by the optical connector 33.

The directional coupler 32 detects the light from the optical connector 33 side as shown by the arrow in the figure and the detector 34.
The detector 34 is connected so as to branch to the side, detects the level of incident light, and controls the laser light source 31 when the level is equal to or higher than a predetermined level to generate laser light. It is configured to stop.

In the optical laser output device having such a configuration, when the optical connector 33 is connected to the optical connector 35 to which the laser light is to be input, the reflection at the end face thereof is sufficiently small, so that the detection is performed. A very low level of light will be input to the container 34, and as a result, the laser light output will be continued. On the contrary, the optical connector 33
Is open, the Fresnel reflection causes a large reflection at the end surface of the optical connector 33 as compared with when the optical connector connection is made.
The laser light (reflected light) of a certain level is input, and the detector 34 stops the output of the laser light.

As described above, when this technique is used, it is possible to automatically identify whether or not the optical connector is connected. However, the optical surge is prevented by the method of detecting the reflected light level at the end face of the optical connector. I can't. Because, in this method, it cannot be judged that the optical connector is connected unless the light of a certain level is continuously sent to the optical connector side.
Light will always be emitted. Therefore, even if an optical transmitter is constructed using this technique, an optical surge will still occur when the optical connector is connected.

Therefore, an object of the present invention is to provide an optical communication system capable of preventing the occurrence of an optical surge due to an erroneous operation.

[0010]

According to the first aspect of the present invention,
(A) A transmission line optical connector is provided at at least one end, and a transmission line to which a pilot signal light that is a signal light that does not depend on the content of information communicated in the system is supplied in the direction of the transmission line side optical connector. (B) Main signal light generating means for generating a main signal light which is signal light containing information to be communicated, and a transmitter side optical connector for outputting the main signal light generated by the main signal light generating means. And extracting means for extracting the pilot signal light incident from the transmitter-side optical connector, and determining the magnitude relationship between the level of the pilot signal light extracted by the extracting means and a predetermined reference level. A determination means for determining the connection state between the transmission side optical connector and the transmission path side optical connector provided in the transmission path, and the determination means connecting the transmitter side optical connector and the transmission path side optical connector. When it is determined that the main signal light is not generated, the main signal light generation unit is controlled so that the main signal light is not generated, and when it is determined that the transmitter side optical connector and the transmission path side optical connector are connected. , The level of the main signal light generated by the main signal generating means is a predetermined time constant,
And an optical transmitter having control means for controlling the main signal light generation means so as to increase the level to the level required for communication.

That is, according to the first aspect of the invention, the transmission is performed by determining the transmission line configured to constantly supply the pilot signal light and whether the pilot signal light is input from the transmission line. When it is determined that the connection with the transmission line has been made by determining the connection state with the line, a predetermined time constant (time constant at which optical surge does not occur)
An optical communication system is formed by an optical transmitter having a function of starting transmission of main signal light while increasing the level.

A directional coupler may be used for supplying the pilot signal light to the transmission line or extracting the pilot signal light, and the wavelength of the pilot signal light is set to the wavelength of the main signal light. May be different from each other, and a wavelength division multiplexing coupler may be used.

[0013]

EXAMPLES The present invention will be described in detail below with reference to examples.

FIG. 1 shows a schematic configuration of an optical communication system according to an embodiment of the present invention. As shown in the figure, the optical communication system of the embodiment includes an optical transmitter 11 including an optical transmission circuit 21, an optical coupler 22, an optical / electrical conversion circuit 23, and a detection circuit 24, a transmission line 13, and an optical transmission line 13. It has an optical connector that connects the transmitter 11 and the transmission path 13.

The transmission line 13 is provided with an optical coupler 25 and a pilot signal generation circuit 26 for generating a pilot signal light having a wavelength different from the main signal. The pilot signal light output from the pilot signal generation circuit 27 is An optical receiver (not shown) is provided at the other end of the transmission path 13 by the optical coupler 25, which is a Wave Division multiplex (WDM) coupler.

The optical coupler 22 provided in the optical transmitter 11 is also a WDM coupler and is configured to branch only the pilot signal light toward the optical / electrical conversion circuit 23. Then, the optical-electrical conversion circuit 23 outputs an electric signal corresponding to the level of the pilot signal light supplied by the optical coupler 22 to the detection circuit 24.

The detection circuit 24 does not connect the transmission line when the level of the input electric signal is smaller than a predetermined threshold value, that is, when the pilot signal light is not input from the optical connector. The optical transmission circuit 21 is controlled so that the optical signal is judged to exist and the optical signal is not transmitted. When the level of the input electrical signal becomes higher than the threshold value, that is, when the pilot signal light starts to be input from the optical connector, it is determined that the connection to the transmission line has been made, and the optical surge So that the level of the transmitted optical signal changes with a time constant that does not occur.
Control.

As described above, in the optical communication system of the embodiment, the optical transmitter automatically detects the connection of the optical connector based on the pilot signal light from the transmission line, and the connection is established. When this happens, the level of the optical signal to be transmitted is raised with a predetermined time constant. Therefore, in this optical communication system, no matter how the optical connector is connected, the light whose level suddenly changes is not input to the transmission line, and the optical connector connection causes an optical surge. There is nothing to do.

In the optical communication system of the embodiment, WDM couplers are used as the optical couplers 22 and 25.
Even if the directional coupler is used, an optical communication system with less loss in the optical coupler can be configured as in the case of using the WDM coupler.

[0020]

As described above in detail, in the optical communication system of the present invention, the presence or absence of the connection of the optical connector is automatically discriminated by the optical transmitter, and when the connection with the transmission line is made. ,
Since the level of the optical signal is increased to a level required for communication with a predetermined time constant, it is possible to reliably prevent the occurrence of an optical surge due to an erroneous operation.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of an optical communication system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a schematic configuration of a conventional optical communication system.

FIG. 3 is a block diagram showing an outline of an optical laser output device described in Japanese Patent Application Laid-Open No. 3-275781, in which whether or not an optical connector is connected is automatically identified.

[Explanation of Codes] 11 Optical Transmitter 12, 33, 35 Optical Connector 13 Transmission Line 21 Optical Transmitting Circuit 22, 25 Optical Coupler 23 Optical / Electric Conversion Circuit 31 Laser Light Source 32 Directional Coupler 34 Detector

Claims (5)

[Claims] 1. A transmission path side optical connector is provided at at least one end, and pilot signal light, which is signal light that does not depend on the content of information communicated in the system, is supplied in the direction of the transmission path side optical connector. A transmission line, a main signal light generating means for generating a main signal light which is a signal light containing information to be communicated, and a transmitter side optical connector for outputting the main signal light generated by the main signal light generating means , Extracting means for extracting the pilot signal light incident from the transmitter-side optical connector, and the level of the pilot signal light extracted by this extracting means, and by determining the magnitude relationship between a predetermined reference level, Discriminating means for discriminating the connection state between the transmission side optical connector and the transmission line side optical connector provided in the transmission line, and the discrimination means is the transmitter side optical connector and the transmission line side optical connector. When it is determined that the optical signal is not connected, the main signal light generating means is controlled so that the main signal light is not generated, and the optical connector on the transmitter side and the optical connector on the transmission path side are connected. When it is determined that the main signal light is generated, the main signal light level generated by the main signal generation means has a predetermined time constant and a control means for controlling the main signal light generation means so as to increase to a level required for communication. An optical communication system comprising: an optical transmitter provided. 2. The optical communication system according to claim 1, wherein the extracting means provided in the optical transmitter uses a directional coupler. 3. The wavelength of the pilot signal light is different from the wavelength of the main signal light, and the extracting means provided in the optical transmitter uses a wavelength division multiplexing coupler. The optical communication system according to claim 1, wherein 4. The optical communication system according to claim 1, wherein the pilot signal light is supplied to the transmission line by using a directional coupler. 5. The wavelength of the pilot signal light is different from the wavelength of the main signal light, and the pilot signal light is supplied to the transmission line by using a wavelength division multiplexing coupler. The optical communication system according to claim 1 or 3, characterized in that