KR20020081708A - Optical Communication Apparatus for NetWork - Google Patents

Abstract

PURPOSE: An optical communication device for a network is provided to transmit and receive information in a same wavelength band using one optical fiber. CONSTITUTION: The first wavelength converting unit(110) receives the first optical signal output from an optical receiver(11) of the first optical communication equipment(10), converts the received first optical signal into the second optical signal, and outputs the converted second optical signal. The first optical transmitting device(210) has the first input terminal(A) for receiving the second optical signal output from the first wavelength converting unit(110), the first input and output terminal(B) for outputting the received second optical signal and receiving the first optical signal from the output signal, and the first output terminal(C) for outputting the first optical signal to an optical receiver(12) of the first optical communication equipment(10). The second optical transmitting device(220) has the second input terminal(D) for receiving the first optical signal output from an optical transmitter(21) of the second optical communication equipment(20), the second input and output terminal(E) for outputting the received first optical signal to the first optical transmitting device(210), and the second output terminal(F) for outputting the second optical signal input from the second input and output terminal(E). The second wavelength converting unit(12) receives the second optical signal output from the second optical transmitting device(220), converts the received second optical signal into the first optical signal, and outputs the converted first optical signal to an optical receiver of the second optical communication equipment(20). One optical fiber(300) optically connects the first optical transmitting device(210) and the second optical transmitting device(220).

Description

Optical Communication Apparatus for NetWork

The present invention relates to an optical communication apparatus for a network, and more particularly, to an optical communication apparatus for a network capable of transmitting and receiving information using one optical fiber.

Optical communication converts information into light at a transmitter of an optical communication device and transmits the information to a receiver of another optical communication device through a transmission medium. At this time, an optical fiber is used as a transmission medium for optical communication.

1 is a schematic diagram illustrating a conventional optical communication system.

Referring to FIG. 1, optical communication devices having the same wavelength band are used for optical communication, and each optical communication device has an optical transmitter and an optical receiver. As described above, when two optical communication equipments having the same wavelength band are used to transmit and receive information with each other, two strands are connected since the optical transmitter of one optical communication device and the optical receiver of another optical communication device are connected to each other by optical fibers. Optical fiber is used.

The optical fiber is a glass wire made of quartz as a main raw material, and the optical fiber is composed of a core having a diameter of 0.01 mm to 0.25 mm and a clad that surrounds the core. Such optical fibers are thin and light, and have an advantage of transmitting optical signals without being affected by electromagnetic noise. Despite these advantages, in the case of connecting two optical fibers for long distance communication, the ends of the optical fiber are cut very flat and polished, and then each optical fiber core and core are made by using an adhesive or a connection connector. There is a difficulty in connecting the parts to be exactly matched, there is a problem that the cost of fiber optic installation increases.

Accordingly, an object of the present invention is to provide an optical communication device for a network that can transmit and receive information in the same wavelength band using one optical fiber.

1 is a schematic diagram illustrating a conventional optical communication system;

2 is a schematic diagram illustrating an optical communication system in which two optical communication devices are optically connected by an optical communication device for a network according to the present invention.

The optical communication apparatus for a network of the present invention for achieving the above technical problem, receives a first optical signal having a wavelength of λ ₁ output from the optical transmitter of the first optical communication equipment and converts it into a second optical signal having a wavelength of λ ₂ A first wavelength conversion unit for outputting; A first input terminal to which the second optical signal output from the first wavelength converter is input, a first input / output terminal to output the input second optical signal and to receive the first optical signal from the outside, and the first input / output terminal First light transmitting means having a first output terminal for outputting the first optical signal inputted toward the optical receiver of the first optical communication equipment; A second input terminal to which the first optical signal outputted from the optical transmitter of a second optical communication device is input, and a second optical signal outputted from the first light transmitting means and outputted to the first light transmitting means; A second light transmitting means comprising a second input / output terminal to which a call is input, and a second output terminal to output the second optical signal input to the second input / output terminal; A second wavelength converting unit which receives the second optical signal output from the second light transmitting means, converts the second optical signal into the first optical signal and outputs the optical signal to an optical receiver of the second optical communication device; And one optical fiber for optically connecting the first light transmitting means and the second light transmitting means.

In this case, the first light transmitting device or the second light transmitting device may include an optical coupler, an optical filter, or a circulator.

Further, the second wavelength conversion unit has an automatic gain control circuit or an automatic power control circuit, and the automatic gain control circuit or the automatic power control between the first output terminal of the first light transmitting means and the optical receiver of the first optical communication equipment. An output drive having a circuit may be further provided, and an input drive having an automatic gain control circuit or an automatic power control circuit may be further provided between the optical transmitter of the second optical communication equipment and the second input terminal of the second light transmitting means.

Furthermore, an optical amplifier may be further provided in the first input / output terminal, the first output terminal, the second input / output terminal, or the second output terminal.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

2 is a schematic diagram illustrating an optical communication system in which two optical communication devices are optically connected by an optical communication device for a network according to the present invention. In FIG. 2, '->' indicates the flow of the optical signal outputted from the first optical communication device, and the " 'Represents the flow of the optical signal output from the second optical communication equipment.

2, an optical communication apparatus for a network according to the present invention includes a first wavelength converting unit 110 optically connected to an optical transmitter 11 of a first optical communication device 10 and a first optical communication device 10. A first wavelength transmission unit 210 optically connected to the optical receiver 12 and the first wavelength conversion unit 110, and a second wavelength conversion optically connected to the optical receiver 22 of the second optical communication device 20; The unit 120, the second light transmitting unit 220 optically connected to the optical transmitter 22 and the second wavelength converting unit 120 of the second optical communication device 20, and the first light transmitting unit 210. ) And a single optical fiber 300 that optically connects the second light transmitting means 220.

The first wavelength converting unit 110 has a 'ga' port as an input terminal and a 'na' port as an output terminal, and has a first optical beam having a wavelength of λ ₁ transmitted from the optical transmitter 11 of the first communication device 10. When the arc is input to the 'ga' port, the arc is converted into a second optical signal having a wavelength of λ ₂ and output to the 'na' port toward the first light transmitting means 210.

The first light transmitting unit 210 is connected to the first wavelength converting unit 110 and an A port as an input terminal to which a second optical signal is input from the first wavelength converting unit 110, and a second light input to the A port. A port B as an input / output terminal for outputting a signal to the optical fiber 300 and a first optical signal transmitted from the second optical transmission means 220 through the optical fiber 300, and an optical receiver of the first optical communication equipment 10. It is connected to the (12) has a C port as an output terminal for outputting the first optical signal input to the B port to the optical receiver 12 of the first optical communication equipment (10).

The second light transmitting means 220 is connected to the optical transmitter 21 of the second optical communication equipment 20 and the D port as an input terminal to which the first optical signal is input from the optical transmitter 21 of the second optical communication equipment 20. And an E port as an input / output terminal to which the first optical signal input through the D port is output to the optical fiber 300, and the second optical signal transmitted from the first optical transmission means 210 through the optical fiber 300 is input. It is connected to the wavelength converter 120 and has an F port as an output terminal for outputting the second optical signal inputted through the E port to the second wavelength converter 120.

The second wavelength converter 120 has a 'd' port as an input terminal and a 'd' port as an output terminal, and inputs the second optical signal output from the F port of the second light transmission unit 220 to the 'd' port. The first optical signal is converted into a first optical signal having a wavelength of λ ₁ , and then outputs toward the optical receiver 22 of the second optical communication device 20 through the 'LA' port.

As an embodiment according to the present invention, an optical coupler, an optical filter or a circulator is used as the first and second light transmitting means 210 and 220. The optical filter, the circulator, or the optical circulator causes the input first or second optical signal to be branched and output to a specific port. However, when the first and second optical communication equipment is used for a long time, the optical power output from each optical transmitter may gradually change. Therefore, there is a need for a separate automatic gain control circuit or automatic power control circuit to keep the output and input levels constant.

In the optical communication device for a network of the present invention, an automatic gain control circuit is provided to the second wavelength conversion unit 120 so that the first optical signal transmitted from the first optical communication device 10 is received by the second optical communication device 20 at a predetermined level. An automatic power control circuit is provided. In addition, an output terminal of the first optical transmission device 210, that is, the C port and the first optical communication device 10 so that the first optical signal transmitted from the second optical communication device 20 is received at the first optical communication device 10 at a constant level. An output drive 400 having an automatic gain control circuit or an automatic power control circuit is further installed between the optical receivers 12). In addition, the second optical communication device 20 such that the first optical signal transmitted from the optical transmitter 21 of the second optical communication device 20 is input to the second input terminal of the second wavelength converter 120, that is, the D port at a predetermined level. An input drive 500 having an automatic gain control circuit or an automatic power control circuit is further installed between the optical transmitter 21 and the second input terminal of the second wavelength converter 120, that is, the D port.

The automatic gain control circuit or automatic power control circuit includes a detector which detects gain or power of an optical signal input to the self, and a reference signal is input to compare the reference signal and the detected signal, and to obtain a gain or power compensation described later. A comparison control unit for controlling the unit and a compensation unit for adjusting the output gain or power of the detected optical signal. Therefore, when the detected optical signal has a smaller gain or power than the reference signal, the compensator increases and outputs the gain or power. When the detected optical signal has a larger gain or power than the reference signal, the compensator obtains a gain or power. To reduce the output.

Meanwhile, although not shown in the input and output terminals of the first light transmitting means 210, that is, the B port and the output terminal, that is, the C port and the input and output terminals of the second light transmitting means 220, i. By installing an optical amplifier, communication can be easily performed not only in a short distance but also in a long distance.

For example, when the optical communication system using the optical communication device for the network of the present invention, the optical signal having a wavelength of 1300 ± 30nm output to the optical transmitter 11 of the first optical communication device 10 is the first wavelength conversion unit 110 ) Is converted into a wavelength of 1500 ± 30nm, and then sequentially passed through the first and second light transmitting means (210, 220) and converted back to 1300 ± 30nm in the second wavelength conversion unit 120 to the second optical communication equipment Input to the optical receiver 22 of (20). The optical signal having a wavelength of 1300 ± 30 nm, which is output to the optical transmitter 21 of the second optical communication device 20, passes through the first and second light transmitting means 210 and 220 sequentially, and then remains as it is. Input to the optical receiver 12 of (10).

As described above, according to the network optical communication apparatus of the present invention, by connecting optical communication equipment between the spaces with a single optical fiber and transmitting and receiving information, it is possible to reduce the cost of the optical fiber installation and improve the utilization rate of the optical fiber.

In addition, by using passive elements such as an optocoupler, a circulator or an optical filter, power consumption can be minimized and used according to the type and speed of the transmitted optical signal. A stable and reliable optical communication network can be established.

The present invention is not limited only to the above embodiments, and it is apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

Claims (6)

In the optical communication device for a network to form a network by connecting a first optical communication device for transmitting and receiving a first optical signal having a wavelength of λ ₁ and the second optical communication equipment, A first wavelength converter which receives the first optical signal output from the optical transmitter of the first optical communication equipment and converts the optical signal into a second optical signal having a wavelength of λ ₂ ; A first input terminal to which the second optical signal output from the first wavelength converter is input, a first input / output terminal to output the input second optical signal and to receive the first optical signal from the outside, and the first input / output terminal First light transmitting means having a first output terminal for outputting the first optical signal inputted toward the optical receiver of the first optical communication equipment; A second input terminal to which the first optical signal output from the optical transmitter of the second optical communication equipment is input, and a second optical signal outputted toward the first light transmitting means and output from the first light transmitting means; A second light transmitting means comprising a second input / output terminal to which an optical signal is input, and a second output terminal to output the second optical signal input to the second input / output terminal; A second wavelength converter which receives the second optical signal output from the second light transmitting means, converts the first optical signal into the first optical signal and outputs the optical signal toward the optical receiver of the second optical communication device; And an optical fiber for optically connecting the first light transmitting means and the second light transmitting means. The optical communication device for a network according to claim 1, wherein the first light transmitting device or the second light transmitting device comprises an optical coupler, an optical filter or a circulator. The optical communication apparatus for a network according to claim 1, wherein the second wavelength conversion unit has an automatic gain control circuit or an automatic power control circuit. An output drive having an automatic gain control circuit or an automatic power control circuit is further provided between the first output terminal of the first light transmitting means and the optical receiver of the first optical communication equipment. An optical communication device for network. The network of claim 1, further comprising an input drive having an automatic gain control circuit or an automatic power control circuit between the optical transmitter of the second optical communication equipment and the second input terminal of the second light transmitting means. Optical communication devices. The optical communication apparatus of claim 1, wherein an optical amplifier is further provided at the first input / output terminal, the first output terminal, the second input / output terminal, or the second output terminal.