KR100681905B1 - Reverse Integrated Optical Repeater - Google Patents

Abstract

The present invention relates to a reverse integrated optical repeater, and receives a reverse signal received from a subscriber station of a first mobile communication system and a second mobile communication system using different frequency bands with one antenna and converts it into an optical signal, An integrated donor module for accommodating a first mobile communication system and a second mobile communication system and an integrated remote module for transmitting to a single donor module for accommodating the second mobile communication system, wherein the integrated remote module includes one antenna; A duplexer for separating the reverse subscriber signal received through each system; A first drive amplifier for amplifying a first mobile communication system reverse signal from the duplexer and a second drive amplifier for amplifying a second mobile communication system reverse signal from the duplexer; A triplexer outputting a signal received from the first drive amplifier and the second drive amplifier in combination with a control signal; An all-optical converter for converting the triplexer output electrical signal into an optical signal; A first wavelength division multiplexing device for transmitting an all-optical converter output optical signal to the integrated donor module through an optical cable, and a second wavelength division multiplexing device for transmitting the all-optical converter output optical signal to the single donor module via an optical cable; Optical switching means for switching the optical signal output from the all-optical converter to the first wavelength division multiplexing device and the second wavelength division multiplexing device; There are technical features to be made, including.

Description

Reverse Path Integrated Optical Repeater

1 is a block diagram of a reverse integrated optical repeater according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: integrated donor module 200: single donor module

300: integrated remote module 110, 120, 210: reverse RF amplifier

130, 350: triplexer 220, 380: duplexer

140, 230: photoelectric converter 150, 240, 310, 320: wavelength division multiplexing device

330 light switching means 331 light splitter

340: all-optical converter 360, 370: drive amplifier

The present invention relates to a reverse integrated optical repeater for receiving and receiving the reverse subscriber signal of the mobile communication systems using different frequency bands. More specifically, one optical repeater remote is connected to each system regardless of the position of the base station of each system. The present invention relates to a reverse integrated optical repeater that receives a reverse subscriber signal and services each base station to enable a low cost optical repeater.

Currently, optical repeaters widely used in mobile communication systems have been utilized in terms of coverage expansion of base stations to extend mobile telephone services to shadowed areas where signals of base stations are difficult to reach.

The optical repeater is composed of a donor module and a remote module connected by an optical cable.In the case of the forward signal, the donor module converts the RF signal of the base station into an optical signal and transmits it to the remote module, and the remote module restores and amplifies it back to the RF signal. To provide services to users. In addition, in the reverse signal, the remote module receives the RF signal from the user terminal, converts it into an optical signal, and transmits it to the donor module, and the donor module restores the RF signal back to the base station.

Meanwhile, as mobile communication systems of several frequency bands coexist, base stations of each mobile communication system are often installed in the same space, and in this case, if a repeater manufactured differently for each system is used, the manufacture and installation of a repeater There is a disadvantage that it is inefficient in cost, installation place, and the like.

Therefore, the development of an integrated repeater has recently been made to enable the service of a single repeater for signals with different frequency bands. However, if the optical repeater is composed of an integrated donor module and an integrated remote module that accepts all signals having different frequency bands, the system can be used only if the base station installation space of each system is the same. If the modules are located in different positions, there is a disadvantage that a separate repeater must be installed for each system.

Accordingly, the present invention is to solve the above-mentioned disadvantages and problems of the prior art, it is possible to service the signal of each mobile communication system using a different frequency band in one optical repeater, each mobile communication system It is an object of the present invention to provide a reverse-integrated optical repeater to enable service through one optical repeater remote module irrespective of the location of the base station.

The above object of the present invention is an integrated remote module for receiving a reverse signal received from the subscriber station of the first mobile communication system and the second mobile communication system using different frequency bands with one antenna and converting it into an optical signal, and an optical cable A base station of the second mobile communication system connected to the integrated remote module through an integrated donor module and an optical cable connected to the integrated remote module and connected to a base station of the first mobile communication system and the second mobile communication system, respectively. An optical repeater comprising a single donor module connected with the integrated remote module, the integrated remote module comprising: a duplexer for separating a reverse subscriber signal received through the one antenna for each system; A first drive amplifier for receiving and amplifying a reverse signal of a first mobile communication system from the duplexer, and a second drive amplifier for receiving and amplifying a reverse signal of a second mobile communication system from the duplexer; A triplexer outputting a signal received from the first drive amplifier and the second drive amplifier in combination with a control signal; An all-optical converter for converting an electrical signal output from the triplexer into an optical signal; A first wavelength multiplexing device for transmitting the optical signal output from the all-optical converter to the integrated donor module through an optical cable, and a second transmitting the optical signal output from the all-optical converter to the single donor module through an optical cable Wavelength division multiplexing device; Interposed between the all-optical converter, the first wavelength division multiplexing device, and the second wavelength division multiplexing device so that the optical signal outputted from the one all-optical converter can be separated and transmitted to the corresponding donor module, Optical switching means for switching the output optical signal to the first wavelength division multiplexing device and the second wavelength division multiplexing device; It is achieved by a backward integrated optical repeater comprising.

Details of the above object and technical configuration of the present invention and the resulting effects thereof will be more clearly understood from the following detailed description based on the accompanying drawings.

1 is a block diagram of a reverse integrated optical repeater according to an embodiment of the present invention.

As shown, the reverse integrated optical repeater of the present invention receives a reverse subscriber signal, converts it into an optical signal, and transmits the optical signal to the donor module, and receives the optical signal from the remote module 300 again to receive RF. It is divided into donor modules 100 and 200 which are converted into signals and transmitted to the base station of the system.

The optical repeater remote module 300 of the present invention is configured to accommodate both reverse subscriber signals to be transmitted to the integrated donor module 100 and the single donor module 200, the integrated donor module 100 is the first mobile communication A single donor module accepts signals from both systems when the base stations of system A (e.g. 2G and 2.5G) and a second mobile communication system B (e.g. 3G) are installed in the same space. 200 is used when the base station position of the second mobile communication system is different from the base station position of the first mobile communication system.

Since the present invention relates to an optical repeater for providing a reverse transmission path, the configuration of the integrated remote module 300 will be described first.

The integrated remote module 300 of the present invention receives the reverse signal received from the subscriber station of the first mobile communication system and the second mobile communication system using different frequency bands with one antenna and converts it into an optical signal. It serves to transmit to the donor module 100 and a single donor module 200.

That is, the duplexer 380 separates the reverse subscriber signal received through the one antenna for each system and transmits the reverse subscriber signal to the first drive amplifier 360 and the second drive amplifier 370.

The first drive amplifier 360 receives and amplifies the reverse signal of the first mobile communication system from the duplexer 380, and the second drive amplifier 370 receives the reverse signal of the second mobile communication system from the duplexer 380. Receives and amplifies, all the amplified signal is input to the triplexer (350).

The triplexer 350 outputs a signal received from the first drive amplifier 360 and the second drive amplifier 370 by combining with a control signal, and the all-optical converter 340 outputs from the triplexer 350. The electrical signal is converted into an optical signal. The all-optical converter 340 is shown as a laser diode module LD.

The optical signal output from the all-optical converter 340 is switched by the optical switching means 330 and transmitted to the wavelength division multiplexer 310, 320, and the first wavelength division multiplexer 310 receives the received signal. To the integrated donor module 100, the second wavelength division multiplexing device 320 transmits to a single donor module 200. In the drawing, the wavelength division multiplexing apparatus 310 and 320 are illustrated as a low density wavelength division multiplexing module (CWDM) as an example.

On the other hand, in the present invention, the optical signal output from one of the all-optical converter 340 can be separated and transmitted to the donor module 100, 200, the all-optical converter 340 and the first wavelength division multiplexing device Optical switching means 330 between the 310 and the second wavelength division multiplexing device 320, the optical switching means 330 and the electrical signal of the first mobile communication system (eg 800MHz band signal) and Separate electrical signals (eg, signals in the 2 GHz band) of the second mobile communication system.

That is, the optical switching means 330 switches the optical signal output from the all-optical converter 340 to the first wavelength division multiplexing device 310 and the second wavelength division multiplexing device 320 and the all-optical converter ( Among the optical signals from 340, an optical signal corresponding to a signal of the second mobile communication system (for example, a signal of 2 GHz band) is simultaneously provided to the first wavelength division multiplexing apparatus 310 and the second wavelength division multiplexing apparatus 320. It comprises a light splitter 331 for.

The integrated remote module 300 of the present invention described above performs both the reverse signal transmission to the integrated donor module 100 and the reverse signal transmission to the single donor module 200, and the integrated donor module 100 and the single donor module 200. The configuration of) is as follows.

First, the wavelength division multiplexing device 150 of the integrated donor module 100 receives an optical signal from the integrated remote module 300 through an optical cable, and the photoelectric converter 140 from the wavelength division multiplexing device 150. The received optical signal is converted into an electrical signal and input to the triplexer 130. In the figure, the photoelectric converter 140 is shown as a photodiode (PD) module.

The triplexer 130 receives an electrical signal output from the photoelectric converter 140, separates a control signal, distributes the control signal into a signal of the first mobile communication system and a signal of the second mobile communication system, and then transmits the first mobile communication system. Signal is output to the first reverse RF amplifier 110, the signal of the second mobile communication system to the second reverse RF amplifier (120).

The first reverse RF amplifier 110 and the second reverse RF amplifier 120 receive and amplify an electric signal input from the triplexer 130, and each of the amplified signals is a base station of the first mobile communication system, Transmit to the base station of the second mobile communication system.

In addition, the wavelength division multiplexing apparatus 240 of the single donor module 200 receives the reverse optical signal transmitted from the subscriber station of the second mobile communication system from the integrated remote module 300 and transmits the reverse optical signal to the photoelectric conversion module 230. The photoelectric conversion module 230 converts the optical signal into an electrical signal and inputs it to the duplexer 220.

The duplexer 220 separates a control signal from the converted electrical signal, inputs a reverse subscriber signal from which the control signal is separated, to the reverse RF amplifier 210, and a reverse RF amplifier 210 amplifies the received signal to generate a first signal. 2 Transmit to base station of mobile communication system.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Therefore, according to the reverse integrated optical repeater of the present invention, the signal of each mobile communication system using different frequency bands can be serviced by one optical repeater, and in particular, regardless of the position of the base station of each mobile communication system, The service is available in the optical repeater remote module, so it can be expected to reduce the production and installation cost of the repeater and secure the repeater installation space.

Claims (3)

An integrated remote module for receiving a reverse signal received from the subscriber station of the first mobile communication system and the second mobile communication system using different frequency bands into one antenna and converting it into an optical signal, The integrated remote module via an optical cable A single donor module connected to the integrated remote module through an integrated donor module and an optical cable connected to the base station of the first mobile communication system and the base station of the second mobile communication system, respectively, and connected to the base station of the second mobile communication system. As an optical repeater comprising a, The integrated remote module, A duplexer for separating the reverse subscriber signal received through the one antenna for each system; A first drive amplifier for receiving and amplifying a reverse signal of a first mobile communication system from the duplexer, and a second drive amplifier for receiving and amplifying a reverse signal of a second mobile communication system from the duplexer; A triplexer outputting a signal received from the first drive amplifier and the second drive amplifier in combination with a control signal; An all-optical converter for converting an electrical signal output from the triplexer into an optical signal; A first wavelength multiplexing device for transmitting the optical signal output from the all-optical converter to the integrated donor module through an optical cable, and a second transmitting the optical signal output from the all-optical converter to the single donor module through an optical cable Wavelength division multiplexing device; Interposed between the all-optical converter, the first wavelength division multiplexing device, and the second wavelength division multiplexing device so that the optical signal outputted from the one all-optical converter can be separated and transmitted to the corresponding donor module, Optical switching means for switching the output optical signal to the first wavelength division multiplexing device and the second wavelength division multiplexing device; Reverse integrated optical repeater, characterized in that comprises a. The method of claim 1, The optical switching means, And an optical splitter for simultaneously providing optical signals corresponding to signals of the second mobile communication system among the optical signals from the all-optical converter to the first wavelength division multiplexing device and the second wavelength division multiplexing device simultaneously. Reverse Integrated Optical Repeater. The method of claim 1, The optical switching means, Reverse integrated optical repeater, characterized in that for separating the signal of the 800MHz band signal and the 2GHz band.

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