KR100246216B1 - Optical multiplexion device - Google Patents

Abstract

The present invention provides a multipath optical multiplexing apparatus capable of multiplexing three-path optical signals including a transmission, reception path, and a reception diversity path, which are optical signal paths between base stations, in a code division multiple access (CDMA) communication system. The present invention relates to a light emitting device comprising: first and second transmitting and receiving parts for transmitting and receiving an optical signal of a first wavelength band; A third transmitting and receiving unit for transmitting and receiving an optical signal of a second wavelength band different from the first wavelength band; The optical signals output from the first and second transmission and reception sections are combined and transmitted to the wavelength division multiplexing unit at the rear end, and the received optical signals of the first wavelength band obtained from the wavelength division multiplexing section are divided to distribute the first and second transmission and reception sections. A first light distribution and coupling unit for transmitting to the light receiving unit; The optical signal of the first wavelength band obtained by the first optical splitter and the combiner and the optical signal of the second wavelength band obtained by the third transmitting and receiving part are optically multiplexed and transmitted to the optical cable, and the optical signals of different wavelength bands received by the optical cable are received. A first wavelength division multiplexing unit which separates the first and second wavelengths and transmits the first light distribution and the combiner and the third transmission and reception unit; A second wavelength division multiplexer for separating the optical signal transmitted through the optical cable for each wavelength, and optically multiplexing the optical signals of the first wavelength band and the second wavelength band to be transmitted to the optical cable; The optical signal of the first wavelength band obtained from the second wave division multiplexing portion is distributed and transmitted to the fourth and fifth transmitting and receiving parts, and the optical signal of the first wavelength band obtained from the fourth and fifth transmitting and receiving parts is combined to form a first signal. A second light distribution and combiner for delivering to the two wavelength division multiplexing unit; A sixth transmission beam which receives the optical signal of the second wavelength band separated by the second wavelength division multiplex and receives the optical signal from the second wavelength division and converts the signal obtained from the rear end into an optical signal of the second wavelength band and transmits the optical signal to the second wavelength division multiplex And by providing a light receiving unit, three-path light multiplexing is possible.

Description

Multipath Optical Multiplexer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical multiplexing apparatus. In particular, an optical multiplexing apparatus can multiplex an optical signal having three paths including a transmission, reception path, and reception diversity path, which are optical signal paths between base stations, in a code division multiple access (CDMA) communication system. A multipath optical multiplexing device is provided.

In general, optical communication is a communication method of transmitting information carried in light through an optical fiber, unlike a wired communication using a metal wire or a wireless communication using a free space.

This optical communication system uses an optical fiber cable as a transmission medium, and includes an electro-optical converter on the transmitting side and an opto-electric converter on the receiving side.

In the optical communication method, an optical signal emitted from a plurality of light emitting elements having different wavelengths on a transmitting side is combined with an optical combiner to transmit a single optical fiber cable, and an optical signal multiplexed on the receiving side. Wavelength Division Multiplexing (“WDM”), a new multiplexing scheme that separates and transmits the beam into optical splitters, is used.

Here, the aforementioned wavelength division multiplexing has the following advantages.

Two-way transmission is possible, and simultaneous transmission of heterogeneous signals (e.g., analog video signal and digital video signal) is generally easy, and it is easy to add lines without additional lines, and the same transmission capacity is divided into several channels for transmission. This is possible because it can be a large capacity.

Therefore, the recent communication system manufacturers have continuously researched and developed the optical communication system using the optical communication method. Among them, the CDMA communication system, which has been in the spotlight recently, attempts to connect each base station by the optical communication method. It is becoming.

However, such a conventional optical communication method has three paths including a transmission and reception path and a reception diversity path when optical communication between a base station and a remote small base station is performed. Due to the lack of development, only two paths can be multiplexed, so there are many problems in applying a complete optical communication method to a communication system.

Herein, the three paths including the reception diversity path will be described in detail.

When the radio wave transmitted from the mobile communication terminal arrives at the CDMA mobile communication base station antenna, the radio wave force is attenuated in the part where it is synthesized and canceled by the phase difference of the signal. Therefore, in today's commercially available mobile communication systems, two reception antennas with different phases are installed, and spatial diversity is implemented to be an optimal reception condition by allowing the reception path to be automatically selected as a path where strong wave strength is received. .

Therefore, two reception paths and one transmission path are provided as a communication system in the base station.

Accordingly, the present invention has been proposed to solve the above problems of the prior art, and the present invention provides an optical signal path between transmission and reception paths and a reception diversity path in a code division multiple access (CDMA) communication system. An object of the present invention is to provide a multipath optical multiplexing device capable of multiplexing an optical signal having three paths.

An apparatus according to the present invention for achieving the above object, the first and second transmitting and receiving unit for transmitting and receiving the optical signal of the first wavelength band; A third transmitting and receiving unit for transmitting and receiving an optical signal of a second wavelength band different from the first wavelength band; The optical signals output from the first and second transmitters and receivers are combined and transmitted to a wavelength division multiplexer at a later stage, and the received optical signals of the first wavelength band obtained from the wavelength division multiplexer are distributed to divide the first and second optical signals. A first light distribution and combiner for transmitting the light transmitting and receiving unit; The optical signal of the first wavelength band obtained by the first optical distribution and combiner and the optical signal of the second wavelength band obtained by the third transmitting and receiving part are optically multiplexed and transmitted to the optical cable, and the optical signal of the different wavelength band received by the optical cable A first wavelength division multiplexing unit for separating the first and second wavelengths and transmitting the first and second wavelengths to the first light distribution and combiner and the third light transmitting and receiving unit; A second wavelength division multiplexer for separating the optical signal transmitted through the optical cable for each wavelength, and optically multiplexing the optical signal of the first wavelength band and the first wavelength band to be transmitted to the optical cable; The optical signals of the first wavelength band obtained by the second wavelength division multiplexing portion are distributed and transmitted to the fourth and fifth transmitting and receiving parts, and the optical signals of the first wavelength band obtained by the fourth and fifth transmitting and receiving parts are combined to A second light distribution and combiner for delivering to the second wavelength division multiplexing unit; The optical signal of the second wavelength band separated by the second wavelength division multiplex is received and transmitted to the rear end, and the signal obtained from the rear end is converted to the optical signal of the second wavelength band and transmitted to the second wavelength division multiplex. It is characterized by consisting of six transmitting and receiving parts.

1 is a block diagram of a multipath optical multiplexer according to the present invention.

* Explanation of symbols for main parts of the drawings

10-30: first to third transmitting and receiving parts

40,80: first and second light distribution and combiner

50,70: first and second wavelength division multiple parts

90-110: fourth to sixth transmitting and receiving parts

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

1 is a block diagram of a multipath optical multiplexer according to the present invention.

As shown therein, first and second transmission and reception units 10 and 20 for transmitting and receiving an optical signal of a first wavelength band (1310 nm); A third transmission and reception unit 30 for transmitting and receiving an optical signal of the first wavelength band 1310 nm and the second wavelength band 1550 nm; The optical signals output from the first and second transmission and reception units 10 and 20 are combined and transmitted to the first wavelength division multiplexing unit 50 at the rear stage, and the optical signals obtained from the first wavelength division multiplexing unit 50 are obtained. A first optical distribution and combiner 40 for distributing the received optical signal of the first wavelength band and transmitting the received optical signal to the first and second transmission and reception units 10 and 20; The optical cable 60 by optically multiplexing the optical signal of the first wavelength band (1310 nm) obtained by the first optical distribution and combiner 40 and the optical signal of the second wavelength band (1550 nm) obtained by the third transmission and reception part 30. And the optical signals of different wavelength bands received by the optical cable 60 are separated into the first and second wavelengths to the first optical distribution and combiner 40 and the third transmission and reception unit 30. A first wavelength division multiplexer 50 for transmitting; A second wavelength division multiplexing unit (70) for separating the optical signal transmitted through the optical cable (60) for each wavelength, and optically multiplexing the optical signals of the first wavelength band and the second wavelength band to be transmitted to the optical cable; The optical signal of the first wavelength band obtained by the second wavelength division multiplexer 70 is distributed and transmitted to the fourth and fifth transmitting and receiving parts 90 and 100, and the fourth and fifth transmitting and receiving parts 90 are provided. A second optical splitter and combiner (80) which combines the optical signal of the first wavelength band obtained in the < RTI ID = 0.0 > 100 < / RTI > The optical signal of the second wavelength band separated by the second wavelength division multiplexer 70 receives the light and transmits it to the rear end, and the signal obtained from the rear end is converted into the optical signal of the second wavelength band and the second wavelength division multiplex ( It consists of a sixth transmission and reception unit 110 for transmitting to 70.

In the multipath optical multiplexing apparatus according to the present invention configured as described above, first, when the first to third transmission and reception units 10-30 are viewed from the transmission side, the first transmission and reception units 10 and 20 respectively transmit and transmit. The signal is converted into an optical signal of a first wavelength band (1310 nm) and transmitted to the first optical distribution and combiner 40.

The first optical splitter and combiner 40 transmits an optical signal of a first wavelength band (1310 nm) obtained from the first and second transmitters and receivers 10 and 20 to an internal optical coupler (not shown). It combines and delivers to the first wavelength division multiplexer 50.

In addition, the third transmission and reception unit 30 converts a signal to be transmitted into an optical signal of a second wavelength band (1550 nm) different from the first wavelength band (1310 nm) and transmits the optical signal to the first wavelength division multiplexer 50. The first wavelength division multiplexer 50 multiplexes the transmitted light of the first and second wavelength bands 1310 nm (1550 nm) by using an internal optical combiner (not shown), and the optical cable 60 Will be sent via

That is, the first wavelength division multiplexer 50 multiplexes three paths of light and transmits the light to the optical cable 60.

The wavelength of the first light transmitting part 10 and the second light receiving part 20 is 1310 nm. The first light distribution and coupling unit 40 has the same light wavelength as the first light transmitting unit 10 and the second light receiving unit 20, and the light traveling direction is opposite. By using the linearity of the light does not interfere with each other by using a device such as a directional optical coupling element or an optical circulator can be combined into one optical cable. In addition, since the third light receiver 30 receives light at a wavelength of 1550 nm, the wavelength is split into a WDM device in the first wavelength division multiplexer 50 from the 1310 nm optical wavelength coupled by the first light distribution and coupling unit 40. And multiplexing is made, and is combined into one strand of the optical cable (60). Therefore, a multipath of three paths can be realized with two wavelengths by using a combination of linearity or directivity of light and two kinds of wavelengths.

Meanwhile, the second wavelength division multiplexer 70 receives the optical signal transmitted to the optical cable 60 and separates each wavelength using an optical splitter (not shown in the drawing) for each wavelength. The light of the first wavelength band (1310nm) is transmitted to the second light distribution and combiner 80, the light of the second wavelength band (1550nm) is transmitted to the sixth light transmitting and receiving unit 110.

Accordingly, the second light distribution and combiner 80 distributes the light of the first wavelength band 1310 nm obtained from the second wavelength division multiplexer 70 to the fourth and fifth transmission and reception units 90 and 100. To pass.

The fourth and fifth transmitters and receivers 90 and 100 convert the optical signals of the first wavelength band, respectively, into electrical signals corresponding to the first and fifth receivers, and transmit the optical signals to the receivers at the rear stages. The light receiving unit 110 also converts the transmitted optical signal of the second wavelength band (1550nm) into an electrical signal corresponding thereto and transmits it to the rear end.

Next, when a signal is transmitted at the receiving side, the optical signal is transmitted through a path opposite to the above-described operation.

That is, the fourth transmission and reception unit 90, 100 converts the signal to be transmitted to the optical signal of the first wavelength band 1310 and transmits to the second optical distribution and combiner 80, the sixth transmission and reception unit 110 converts a signal to be transmitted into an optical signal of a second wavelength band (1550 nm) and transmits the converted signal to the second wavelength division multiplexer 70.

Accordingly, the second optical splitter and combiner 80 combines the optical signals of the first wavelength band (1310 nm) coming through the respective paths, and transmits the optical signals to the second wavelength division multiplexer 70. The division multiplexer 70 transmits the light of the optically coupled first wavelength band (1310 nm) and the light of the second wavelength band (1550 nm) obtained from the sixth transmitting and receiving part 110 to the optical cable 60. .

The optical signal transmitted through the optical cable 60 is transmitted to the first wavelength division multiplexer 50 on the transmitter side, and the first wavelength division multiplexer 50 separates the transmitted optical signal for each wavelength. The light of the first wavelength band (1310 nm) is transmitted to the first light distribution and combiner 40, and the light of the second wavelength band (1550 nm) is transmitted to the third light transmission and light receiver 30.

Then, the first light splitter and the combiner 40 distributes the light of the first wavelength band 1310 nm obtained from the first wavelength division multiplexer 50 to the light splitter so that the first and second transmitting and receiving parts 10 and 20 are provided. And the first and second transmitting and receiving units 10 and 20 convert the optical signals of the first wavelength band (1310 nm) to be converted into corresponding electrical signals and output the respective signals. .

In addition, the third transmission and reception unit 30 converts an optical signal of the second wavelength band (1550 nm) obtained from the first wavelength division multiplexer 50 into an electrical signal corresponding thereto and outputs the converted signal.

Therefore, the present invention enables optical multiplexing of a total of three paths by using two paths of the first wavelength band and one path of the second wavelength band.

As described above, the present invention is capable of multiplexing a total of three paths of optical signals by using two wavelength paths of the first wavelength band and one optical path of the second wavelength band by using a wavelength division multiplexer and a photolysis / combiner. There is.

Claims (1)

First and second transmitters and receivers for transmitting and receiving an optical signal of a first wavelength band; A third transmitting and receiving unit for transmitting and receiving an optical signal of a second wavelength band different from the first wavelength band; The optical signals output from the first and second transmitters and receivers are combined and transmitted to a wavelength division multiplexer at a later stage, and the received optical signals of the first wavelength band obtained from the wavelength division multiplexer are distributed to divide the first and second optical signals. A first light distribution and combiner for transmitting the light transmitting and receiving unit; The optical signal of the first wavelength band obtained by the first optical distribution and combiner and the optical signal of the second wavelength band obtained by the third transmitting and receiving part are optically multiplexed and transmitted to the optical cable, and the optical signal of the different wavelength band received by the optical cable A first wavelength division multiplexing unit for separating the first and second wavelengths and transmitting the first and second wavelengths to the first light distribution and combiner and the third light transmitting and receiving unit; A second wavelength division multiplexing unit for separating the optical signal transmitted through the optical cable for each wavelength, and optically multiplexing optical signals of the first wavelength band and the second wavelength band to be transmitted to the optical cable; The optical signals of the first wavelength band obtained by the second wavelength division multiplexing portion are distributed and transmitted to the fourth and fifth transmitting and receiving parts, and the optical signals of the first wavelength band obtained by the fourth and fifth transmitting and receiving parts are combined to A second light distribution and combiner for delivering to the second wavelength division multiplexing unit; The optical signal of the second wavelength band separated by the second wavelength division multiplex is received and transmitted to the rear end, and the signal obtained from the rear end is converted to the optical signal of the second wavelength band and transmitted to the second wavelength division multiplex. 6. A multi-path optical multiplexing device comprising a transmitting and receiving unit.