KR200396300Y1 - Optical communication apparatus - Google Patents

Abstract

Conventionally, in order to bidirectionally communicate with one optical fiber, two wavelengths or an expensive optical element circulator are used. When two wavelengths are used in one optical fiber, a large amount of wavelengths are required to transmit a large capacity, thereby limiting a large capacity transmission. The present invention uses an optical connector and isolator to enable bidirectional communication by using one wavelength for one optical fiber. According to the present invention, it is possible to solve the cost problem of using an expensive circulator by using an inexpensive optocoupler, and bidirectional communication is possible with one wavelength. It is possible to transmit variously in a ring or tree structure as it is without converting various transmission signals such as Internet signals into specific protocols.

Description

Optical communication apparatus

The present invention relates to an optical communication device, and more particularly, to an optical communication device in which bidirectional communication is performed at one wavelength through one optical fiber.

Conventionally, two wavelengths have been used for bidirectional communication with one optical fiber. Since many wavelengths are required to send a large amount of information, using two wavelengths in one optical fiber has a limitation in transmitting large amounts of information. Therefore, in order to solve this shortage, all transmission signals are converted into a certain protocol and then transmitted, which is a factor of system complexity and cost increase.

In order to overcome this problem, a case of using one wavelength has been proposed, but at this time, an expensive optical device, a circulator, is used, which is not preferable in terms of cost.

Therefore, the technical problem to be achieved by the present invention is to provide an optical communication device capable of bidirectional communication through one optical fiber and one wavelength by using an inexpensive optical coupler instead of an expensive circulator.

An optical communication apparatus according to the present invention for achieving the above technical problem,

A first optical receiver and a second optical receiver comprising an optical transmitter and an optical receiver, respectively;

It has three ports A1, B1, and C1, and the B1 port is optically connected to the A1 and C1 ports, respectively, wherein the A1 port is connected to the optical transmitter of the first optical receiver through an optical fiber and the C1 port. A port comprising: a first optical coupler connected to an optical receiver of the first optical receiver through an optical fiber;

It has three ports A2, B2, and C2, and the B2 port is optically connected to the A2 and C2 port, respectively, wherein the A2 port is connected to the optical transmitter of the second optical receiver through an optical fiber and the C2 A port comprising: a second optical coupler connected to the optical receiver of the second optical receiver through an optical fiber;

The light of the first optical receiver so that the light travels only from the optical transmitter of the first optical transmitter toward the first optical coupler and only the light of the second optical coupler of the second optical transmitter is directed toward the second optical coupler A transmission optical isolator provided between the transmitter and the first optical coupler and between the optical transmitter and the second optical coupler of the second optical transmitter; And

And one optical fiber connecting the B1 port of the first optical coupler and the B2 port of the second optical coupler.

Here, the first optical coupler of the first optical receiver so that light travels only toward the optical receiver end of the first optical receiver and the second optical coupler is directed toward the optical receiver end of the second optical receiver. A receiving optical isolator may be installed between the optical receiver and the first optical coupler, and between the optical receiver and the second optical coupler of the second optical transmitter.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. The following examples are only presented to understand the contents of the present invention, and those skilled in the art will be capable of many variations within the technical spirit of the present invention. Therefore, the scope of the present invention should not be construed as limited to these embodiments.

1 is a view for explaining an optical communication apparatus according to the present invention, taking the WDM-PON as an example. As shown in FIG. 1, if the subscriber has 16 homes, they can communicate with the OLT in 16 wavelengths.

A configuration capable of bidirectional communication with one optical fiber and one wavelength will be described with reference to FIG. 2. Referring to FIG. 2, the first optical transmitter 100a and the second optical receiver 100b include optical transmitters 101a and 101b and optical receivers 102a and 102b, respectively. For example, the first optical transmitter 100a may be an OLT, and the second optical transmitter 100b may be viewed as an RN.

The first optical coupler 200a and the second optical coupler 200b are installed between the first optical transmitter 100a and the second optical transmitter 100b. The first optocoupler 200a has three ports A1, B1, and C1, and the B1 port is optically connected to the A1 and C1 ports, respectively. The second optical coupler 100b also has three ports A2, B2, and C2, and the B2 port is optically connected to the A2 and C2 ports, respectively.

The A1 port of the first optical coupler 200a is connected to the optical transmitter 101a of the first optical receiver through an optical fiber, and the C1 port is connected to the optical receiver 102a of the first optical transmitter through an optical fiber. The A2 port of the second optical coupler 200b is connected to the optical transmitter 101b of the second optical receiver through an optical fiber, and the C2 port is connected to the optical receiver 102b of the second optical receiver via an optical fiber.

The first transmission optical beam between the optical transmission terminal 101a of the first optical transmitter and the first optical coupler 200a so that the light travels only from the optical transmission terminal 101a of the first optical receiver to the first optical coupler 200a. An isolator 301a is installed. In addition, a second transmission light is provided between the optical transmitter 101b and the second optical coupler 200b of the second optical receiver so that the light travels only from the optical transmitter 101b of the second optical receiver to the second optical coupler 200b. Isolator 301b is installed.

The first receiver optical is between the optical receiver 102a of the first optical receiver and the first optical coupler 200a so that the light travels only from the first optical coupler 200a toward the optical receiver 102a of the first optical receiver. An isolator 302a is installed. In addition, the second optical receiver 200b has a second optical receiver 200b between the optical receiver 102b and the second optical coupler 200b of the second optical receiver so that the light travels only toward the optical receiver 102b of the second optical receiver 200b. An isolator 302b is installed. The B1 port of the first optical coupler 200a and the B2 port of the second optical coupler 200b are connected by one optical fiber 400. The first receiving optical isolator 302a and the second receiving optical isolator 302b are not necessarily present, and the present invention can be obtained even without them.

The optical signal output from the optical transmitting end 101a of the first optical receiver is input to the A1 port of the first optical coupler 200a via the first transmitting optical isolator 200a and output to the B1 port to provide the optical fiber 400. Through the input to the B2 port of the second optical coupler (200b) is distributed to the A2 and C2 port. At this time, the distribution ratio of the A2 port and the C2 port may be set in advance. Anyway, the light exiting the A2 port does not reach the optical transmitter 101b due to the directionality of the second optical isolator 301b, and the C2 port Only the light exiting through the device passes through the second receiving optical isolator 302b to reach the optical receiving end 102b of the second optical transmitter. Accordingly, the first optical transmitter 100a and the second optical receiver 100b may be bidirectionally communicated through one optical fiber and one wavelength.

As described above, according to the present invention, it is possible to solve the cost problem of using an expensive circulator by using an inexpensive optocoupler, and also, by using an extra wavelength, analog broadcasting is possible because bidirectional communication is possible with one wavelength. Various transmission signals such as signals, digital broadcast signals, and Internet signals can be transmitted in a ring or tree structure without being converted into specific protocols.

1 and 2 are views for explaining the optical communication device according to the present invention.

<Description of reference numbers for the main parts of the drawings>

100a: first optical transceiver 100b: second optical transceiver

101a, 101b: optical transmitter 102a, 102b: optical receiver

200a: first optical coupler 200b: second optical coupler

301a: first transmitting optical isolator

301b: optical isolator for second transmission

302a: first receiving optical isolator

302b: second receiving optical isolator

Claims (4)

A first optical receiver and a second optical receiver comprising an optical transmitter and an optical receiver, respectively; It has three ports A1, B1, and C1, and the B1 port is optically connected to the A1 and C1 ports, respectively, wherein the A1 port is connected to the optical transmitter of the first optical receiver through an optical fiber and the C1 port. A port comprising: a first optical coupler connected to an optical receiver of the first optical receiver through an optical fiber; It has three ports A2, B2, and C2, and the B2 port is optically connected to the A2 and C2 port, respectively, wherein the A2 port is connected to the optical transmitter of the second optical receiver through an optical fiber and the C2 A port comprising: a second optical coupler connected to the optical receiver of the second optical receiver through an optical fiber; The light of the first optical receiver so that the light travels only from the optical transmitter of the first optical transmitter toward the first optical coupler and only the light of the second optical coupler of the second optical transmitter is directed toward the second optical coupler A transmission optical isolator provided between the transmitter and the first optical coupler and between the optical transmitter and the second optical coupler of the second optical transmitter; And And one optical fiber connecting the B1 port of the first optical coupler and the B2 port of the second optical coupler. 2. The light emitting device of claim 1, wherein the light travels only from the first optical coupler toward the light receiving end of the first optical transmitter and from the second optical coupler toward the optical receiving end of the second optical receiver. And an optical isolator for receiving is provided between the optical receiver of the one optical receiver and the first optical coupler and between the optical receiver of the second optical receiver and the second optical coupler. The optical communication apparatus according to claim 1, wherein the first optical receiver and the second optical receiver are used for a WDM-PON. The optical communication apparatus of claim 1, wherein only one wavelength is transmitted through an optical fiber connecting the B1 port of the first optical coupler and the B2 port of the second optical coupler.