KR20020012944A - Optical Add Drop Multiplexer - Google Patents

Abstract

PURPOSE: An optical add drop multiplexer(OADM) is provided, which has both of a multiplexing and a demultiplexing function without using a demultiplexer and a multiplexer respectively. CONSTITUTION: The optical add drop multiplexer comprises an optical demultiplexer(120), optical amplifiers(410,420), a transponder(300) and circulators(510,520,530), which are connected optically each other. A wavelength division multiplexed signal is inputted to an input optical amplifier(410), which compensates an optical loss of the signal due to an optical path. Then, the signal is inputted to an A port of the input/output circulator from the input optical amplifier, and is output through a B port of the input/output circulator and is inputted to a node of the first input/output terminal of the optical demultiplexer. The signal is then is demultiplexed to a branch optical signal and a pass optical signal. The optical signal is converted into a coupled optical signal, which is inputted to an F port of the second circulator from the transponder. And the coupled optical signal is inputted to the demultiplexer through the second input/output node of the demultiplexer from a D port of the second circulator.

Description

Optical Add Drop Multiplexer

The present invention relates to an optical add drop multiplexer (OADM), and more particularly, to an optical add drop multiplexer (OADM) in which an optical multiplexer and an optical multiplexer are integrated.

Transmission technology is classified into a wired transmission technology and a wireless transmission technology, and wired transmission technologies generally used for high-capacity communication vary depending on transmission media such as copper wire, coaxial cable, and optical fiber. At present, the most important transmission technology is a transmission technology using optical paths, and many studies are being conducted to increase transmission capacity and increase transmission distance.

The technique of transmitting and receiving a large number of signals in one line among transmission technologies is called a multi-communication technology. Multiple communication technologies include code division multiplexing (CDM), time division multiplexing (TDM), and wavelength division multiplexing (WDM).

In time division multiplexing, multiple electronic signals are temporally multiplexed and transmitted in a single light beam. Therefore, advances in device technology have to be preceded due to limitations in the speed of electronic devices. In the code division multiplexing scheme, multiple electronic signals are multiplexed according to codes and transmitted in a single light beam. Wavelength division multiplexing is a method that modulates multiple signals to different wavelengths and transmits them through a single optical path. Therefore, the speed of current electronic equipment can be fully utilized because it does not require a fast device to multiplex multiple wavelengths. In particular, the Dense Wavelength Division Multiplexing (DWDM) method can transmit up to about 80 light wavelengths simultaneously in a single optical path at a speed of about 400 Gbps. Therefore, the wavelength division multiplexing method is favored among the above three methods, and related researches are being actively conducted.

1 is a schematic diagram of a conventional optical branching / combining multiplexer used in a wavelength division multiplexing system.

Referring to FIG. 1, the optical branching / combining multiplexer of the present invention includes a multiplexer 110, an optical multiplexer 200, an optical amplifier 410, 420, and a transponder 300, each of which is a component. Are optically connected. 1 shows the flow of the wavelength division multiplexed signal and the optical signal.

The wavelength division multiplexed signal transmitted from the outside is input to the wide multiplexer 110 through a transmission medium such as an optical path. At this time, by providing the input optical amplifier 410 in front of the multiplexer 110, the optical loss of the wavelength division multiplexed optical signal generated in the transmission medium is compensated. The wavelength division multiplexed signal input to the wide multiplexer 110 is demultiplexed into output optical signals having different wavelengths λ ₁ , λ ₂ ,..., Λ _n . The output optical signals are output to the optical multiplexer 200 and the optical receiver 700 separately provided through the respective nodes installed in the multiplexer 110.

The optical signal having a wavelength of λ ₁ among the output optical signals is transmitted to a separate optical receiver 700 provided outside. Hereinafter, the output light signal transmitted to the outside in this manner is referred to as a 'branch light signal'. An optical signal having a wavelength of λ ₂ among the output optical signals is transmitted to the optical multiplexer 200. Hereinafter, the output optical signal that is not transmitted to the optical receiver 700 separately provided in this way is referred to as a 'passing optical signal'.

And an optical signal having a wavelength λ ₁ ⁰ transmitted from the optical transmitter 800 provided separately on the outside is converted to an optical signal having a wavelength of the same λ ₁ and the split optical signal by the transponder (Trasponder) (300). The optical signal having a wavelength of λ ₁ output from the transponder 300 is transmitted to the optical multiplexer 200. Hereinafter, the optical signal transmitted from the optical transmitter 800 separately provided in the outside and then converted by the transponder 300 is referred to as a 'coupled optical signal'.

In the above description, the branched light signal, the combined light signal, and the pass light signal have been described with only one optical signal as an example, but the branched light signal, the combined light signal, and the passed light signal are each composed of at least one optical signal. . Therefore, at least one optical receiver, optical transmitter, and transponder are also provided.

The optical multiplexer 200 multiplexes the input pass light signal and the combined optical signal into a wavelength division multiplexed signal, and the wavelength division multiplexed signal is transmitted to the output optical amplifier 420. The wavelength division multiplexed signal input to the output optical amplifier 420 compensates for the optical signal lost by the optical multiplexer 200 and then is transmitted to another optical branch / combined multiplexer.

As such, the optical branching / combining multiplexer used in the conventional wavelength division multiplexing system is used with the optical multiplexer and the optical multiplexer having the same optical characteristics. In this case, the wavelength multiplexer and the optical multiplexer have a problem that the optical characteristics of the optical signal are deteriorated because the wavelength is changed by the surrounding environment such as temperature.

Accordingly, an aspect of the present invention is to provide an optical branching / combining multiplexer using only a multiplexer having a multiplexing function and a demultiplexing function, without using a wide multiplexer and an optical multiplexer, respectively.

1 is a schematic diagram of a conventional optical branching / combining multiplexer used in a wavelength division multiplexing system;

2 is a schematic diagram of an optical branching / combining multiplexer according to the present invention.

The optical splitting / combining multiplexer of the present invention for achieving the above technical problem has a first input and output terminal having one node to which the wavelength division multiplexed optical signal is input and output, and also has a wavelength that is different from the output of output optical signals having different wavelengths. A wide multiplexer for performing multiplexing and demultiplexing functions, including a second input / output terminal having at least one node to which the combined optical signals are input; It has an input / output port, an output port and an input port, and the input / output port is installed to be connected to a node of the second input / output terminal to output the output optical signals of the second input / output terminal through its own input / output port and output port to the outside. And an input / output means for providing the combined optical signals to be input to the second input / output terminal to the node of the second input / output terminal through its input port and input / output port.

At this time, the third input and output terminal having at least one node for outputting the output optical signals having a different wavelength; The input / output port is installed to be connected to a node of the third output terminal, and the input port and the output port are optically connected to return the output optical signal output from the node of the third input / output terminal back to the third input / output terminal. It may further comprise a connected input and output means.

Further, the branching / combining and passing switching means may consist of a coupler or a circulator.

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

2 is a schematic diagram of an optical branching / combining multiplexer according to the present invention.

Referring to FIG. 2, the optical branch / combination multiplexer of the present invention includes a multiplexer 120, an optical amplifier 410, 420, a transponder 300, and a circulator 510, 520, 530. The components are optically connected. In FIG. 2, '→' and '↔' show the flow of the wavelength division multiplexed signal and the optical signal.

A wavelength division multiplexed signal transmitted over a transmission medium, such as an optical path, is first input to an input optical amplifier 410. The input optical amplifier 410 compensates for the optical loss of the wavelength division multiplexed signal by the transmission medium. The wavelength division multiplexed signal compensated for the optical loss is output from the input optical amplifier 410 and input to the input / output circulator 510.

The input / output circulator 510 has A, B, and C ports, and the signal input to the A port is output to the B port, and the signal input to the B port is configured to output to the C port. Here, the A port of the input / output circulator 510 is an input optical amplifier 410, the B port is a first input / output node node of the global multiplexer 120, and the C port is optically connected to the output optical amplifier 420. It is connected. Accordingly, the wavelength division multiplexed signal output from the input optical amplifier 410 is input to the A port of the input / output circulator 510, and then is output to the B port and input to the node of the first input / output terminal of the wide multiplexer 120. .

The wide multiplexer 120 is configured to demultiplex the wavelength division multiplexed signal into an optical signal, and to multiplex the optical signal into the wavelength division multiplexed signal. The wavelength division multiplexed signal input through the node of the first input / output terminal of the wide multiplexer 120 is demultiplexed into a split light signal and a pass light signal having different wavelengths. The branch light signal and the pass light signal respectively output from the second and third input / output node nodes of the multiplex multiplexer 120 are input to the input / output means, that is, the second circulator 520 and the third circulator 530, respectively.

The second circulator 520 has a D port as an input / output port, an E port as an output port, and an F port as an input port. The signal input to the D port is output to the E port, and the signal input to the F port is the D port. It is configured to output. Here, the D port of the second circulator 520 is optically connected to the second input / output terminal node of the global multiplexer 120. The E port and the F port of the second circulator 520 are optically connected to the optical receiver 700 and the transponder 300 by using jump codes 610 and 620, respectively. The transponder 500 is optically connected to the optical transmitter 800. Accordingly, the branch light signal output from the second input / output terminal node of the multiplex multiplexer 120 is input to the D port of the second circulator 520 and then output to the E port so as to be separately provided to the outside. Is sent to. In addition, a separate optical signal output from the optical transmitter 800 separately provided to the outside is transmitted to the transponder 300. The optical signal transmitted to the transponder is converted into a combined optical signal having the same wavelength as the branched optical signal by the transponder 300 and then output from the transponder 300 to be input to the F port of the second circulator 520. do. The combined optical signal input to the F port of the second circulator 520 is output to the D port and input to the wide multiplexer 120 through the second input / output terminal node of the wide multiplexer 120.

The third circulator 530 has a G port as an input / output port, an H port as an output port, and an I port as an input port. The signal input to the G port is output to the H port, and the signal input to the I port is G. It is configured to output to the port. The G port of the third circulator 530 is optically connected to the third input / output node of the global multiplexer 120, and the H port and the I port of the third circulator 530 are jump codes 630. 640 is optically connected to each other. Accordingly, the pass light signal output from the third input / output terminal node of the wide multiplexer 120 is input to the G port of the third circulator 520 and then passes through the H port and the I port of the third circulator 530. Output to G port. The passing optical signal output to the G port of the third circulator 520 is fed back to the wide multiplexer 120 through the third input and output terminal node of the wide multiplexer 120.

Meanwhile, after the optical connection between the H port and the I port of the third circulator 530 is released, an optical receiver provided separately is optically connected to the H port of the third circulator 530, and the third circulator 530. The third circulator 530 is used for the purpose of the second circulator 520 by optically connecting the transponder and the optical transmitter separately provided to the I port of the). In addition, the optical connection between the E port of the second circulator 520 and the optical receiver 700, the optical connection between the F port and the transponder 300, and then the second circulator 520 of the second circulator 520. By optically connecting the E port and the F port with each other, the second circulator 530 is used for the purpose of the third circulator 530.

The combined light signal and the pass light signal input to the wide multiplexer 120 are multiplexed into a wavelength division multiplexed signal. The wavelength division multiplexed signal is input to the B port of the input / output circulator 510 and then output to the C port and input to the output optical amplifier 420. The output optical amplifier 420 compensates for the signal lost by the multiplexer 120, and then outputs the wavelength division multiplexed signal to another optical branch / combined multiplexer.

As described above, according to the wavelength division multiplexing system of the present invention, by using the multiplexer in which the multiplexer simultaneously performs the optical multiplexing function, the number of components whose center wavelength deviates from the reference value by the temperature or the surrounding environment is reduced so that the wavelength division is performed. The multiplexing system can be kept stable.

Furthermore, wavelength division multiplexing systems can be constructed at lower cost than before.

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 (3)

A first input / output terminal having one node into which the wavelength division multiplexed optical signal is input / output, and a second input / output terminal having at least one node into which outputs of output optical signals having different wavelengths and input of combined optical signals having different wavelengths are input; Including a multiplexer and a multiplexer to perform the function of multiplexing and demultiplexing; It has an input / output port, an output port and an input port, and the input / output port is installed to be connected to a node of the second input / output terminal to output the output optical signals of the second input / output terminal through its own input / output port and output port to the outside. And an input / output means for providing the combined optical signals to be input to the second input / output terminal to a node of the second input / output terminal through its input port and input / output port. The display device of claim 1, further comprising: a third input / output terminal having at least one node to which output optical signals having different wavelengths are output; The input / output port is installed to be connected to a node of the third output terminal, and the input port and the output port are optically connected to return the output optical signal output from the node of the third input / output terminal back to the third input / output terminal. An optical branch / combination multiplexer further comprising connected input / output means. The optical splitter / coupled multiplexer according to claim 1 or 2, wherein the input / output means comprises a coupler or a circulator.