KR20010097981A - Optical repeater - Google Patents

Abstract

Disclosed is an optical relay system that converts an RF signal received from a base station into an optical signal and connects multiple relay stations in parallel to one hub in parallel and / or in series, thereby reducing the cost of installing the relay station and increasing operational efficiency. . The optical relay system according to the present invention converts an RF signal input from a base station into an optical signal and transmits it in the forward direction, amplifies and branches the converted optical signal, and transmits the branched optical signal through an optical path. ; An optical splitter for distributing an optical signal transmitted through the optical arc; And

It is connected in parallel and / or serially to the output side of the optical splitter, receives the divided optical signal and converts it into an RF signal, and transfers the converted RF signal to the user of the terminal through an antenna, the RF signal supplied from the user It is received through the antenna to convert the optical signal, and includes a plurality of repeaters for transmitting the converted optical signal to the hub through the optical transmission path, a plurality of repeaters may be installed in one hub.

Description

Optical repeater {OPTICAL REPEATER}

The present invention relates to an optical relay system, and more particularly, to a device capable of reducing the cost of installing a relay station and increasing operational efficiency by connecting a plurality of relay stations in series or in parallel to one hub. will be.

As is widely known, coverage expansion in a mobile communication network is implemented by an expansion of a base station or a repeater, and an optical repeater system for a mobile communication using a conventional wavelength division multiplexing scheme is illustrated in FIG. 1.

A mobile communication terminal in one base station service area can connect with another terminal subscriber in a service area of another base station, but cannot access when the other mobile terminal or its mobile terminal is out of the base station service area.

It is necessary to install as many base stations as possible to solve such service area limitation, but economic problems on base station equipment cost must be considered in mountainous areas or island areas where the utilization efficiency is lower than the base station expansion cost.

In urban areas, there is an excessive user waiting problem more than the number of subscribers allocated to each base station. As a result, the coverage of the base stations is getting narrower and the gap between the base stations is becoming tighter. Despite the sparse installation under the set conditions, the number of times of use is insignificant compared to the city center, which is a burden on the mobile operator.

Therefore, in the mobile communication network, a small base station or repeater is installed to enable communication in a shaded area such as a mountain area or a suburban area where the usage is low.

In the mobile communication base station provided with the wavelength division optical repeater, as shown in FIG. 1, the base station 11 and one repeater 13 are connected by a hub 12, and the base station 11 and the hub are connected. 12 is wired, and the hub 12 and the repeater 13 are connected by optical communication using a single mode optical fiber. That is, the forward transmission of the repeater 13 from the hub 12 and the reverse transmission from the repeater 13 to the hub 12 enable bidirectional communication using a weight division multiplexing method, and use one optical fiber.

Since only one or two repeaters 13 are connected to the hub 12 due to the limitation of the transmission distance due to the optical loss and the facility cost, each hub and the repeater may be solved in order to solve several shadow areas within one base station coverage. There is a problem in that the number of optical lines increases because it must be installed separately.

Accordingly, the present invention was created to solve the above problems, and an object of the present invention is to provide an optical relay system in which a plurality of repeaters are connected in series and / or in parallel to one hub.

The optical relay system according to the first aspect of the present invention for achieving the above object, converts the RF signal input from the base station into an optical signal and transmits it in the forward direction, and amplifies and branched after the converted optical signal And a hub for transmitting the branched optical signal through the optical path;

An optical splitter for distributing an optical signal transmitted through the optical arc; And

It is connected in parallel and / or serially to the output side of the optical splitter, receives the divided optical signal and converts it into an RF signal, and transfers the converted RF signal to the user of the terminal through an antenna, the RF signal supplied from the user It is composed of a plurality of repeaters for receiving through the antenna to convert the optical signal, and to transmit the converted optical signal to the hub through the optical transmission path.

According to the present invention, since a single hub is connected to a plurality of repeaters using one optical path, the optical path cost can be significantly reduced.

1 is a view showing the configuration of a general optical repeater.

Figure 2 is a block diagram showing the configuration of an optical repeater according to the present invention.

3 is a view showing in detail the configuration of the hub of FIG.

4 is a diagram illustrating a configuration of the repeater of FIG. 2.

<Explanation of symbols for main parts of drawing>

100: base station 200: hub

211: RF signal processing unit 212, 415: all-optical converter

213, 412: photoelectric converter 214: optical amplifier

215, 300: optical splitter 216, 411: optical branch coupling part

Hereinafter, the present invention will be described in more detail with reference to the following examples.

2 is a block diagram illustrating an optical relay system according to the present invention, and includes a base station 100, a hub 200, an optical splitter 300, a first repeater 400, and a second repeater 500.

Here, the hub 200 is configured to convert the RF signal supplied from the base station 100 into an optical signal and transmit it in the forward direction, and convert the optical signal transmitted in the reverse direction into an RF signal and transmit the RF signal to the base station. 300 is provided to distribute the optical signal converted in the hub 200 to a plurality of repeaters 400 (500).

The first repeater 300 converts an optical signal distributed from the optical splitter 300 into an RF signal and transmits the RF signal to a terminal user through an antenna, and receives an RF signal transmitted from the user through an antenna. It is provided to convert the RF signal into an optical signal to transmit to the hub (200).

The configuration of the hub 200 is as shown in FIG. That is, the output side of the base station 100 removes an RF signal of a predetermined band among the RF signals, amplifies and converts a frequency, filters, amplifies, and frequency converts a signal transmitted from the repeater 300 to the base station 100. An RF signal processing unit 211 of the transmitting hub 200 is connected, and on the output side of the RF signal processing unit 211, an all-optical converter 212 and a repeater (for converting the RF signal of the RF signal processing unit 211 into an optical signal) Photoelectric converters 213 for converting optical signals supplied from 300 into electrical signals are respectively connected.

Here, the all-optical converter 212 is provided to convert an RF signal into an optical signal using a light emitting element such as a laser diode or a light emitting diode, and the photoelectric converter 213 is used to convert the optical signal using a light receiving element such as a photodiode. It is provided to convert to a signal.

An optical amplifier 214 for amplifying the optical signal is connected to the output side of the all-optical converter 212, and the optical amplifier 214 may use an optical amplifier or a semiconductor optical amplifier including an optical fiber added with cadmium. Can be.

An optical splitter 215 is connected to the output side of the optical amplifier 214 for splitting the amplified optical signal into a plurality of optical signals, and a splitting of the forward optical signal and the reverse optical signal to each output side of the optical splitter 215 is performed. The directional light splitting coupler 216 that couples is connected.

Here, the optical branch coupling unit 216 is provided to add or branch up and down optical signals using an optical circulator or a wavelength division multiplexer.

The optical signal output from the optical branch coupling unit 216 is provided to be supplied to the optical splitter 300 through an optical path. Then, the optical splitter 300 divides the optical signal transmitted from the upstream by a specific ratio, transmits a part of the distributed optical signal to the first repeater 400, and outputs the optical signal of the remaining part of the optical signal. 2 is provided to transmit to the repeater 500.

As shown in FIG. 4, the first repeater 400 receiving a portion of the optical signal includes an optical coupling branch 411, a photoelectric converter 412, an RF signal processing unit 413, a relay station 414, and an all-optical light. A converter 415 is provided, wherein the configuration of the light coupling branch 411, the photoelectric converter 412, the RF signal processing unit 413, the relay station 414, and the all-optical converter 415 are shown in FIG. 3. The branch unit 216, the photoelectric converter 213, the RF signal processor 211, and the all-optical converter 212 are configured in the same manner.

In the optical relay system according to the present invention configured as described above, a process of first transmitting the RF signal of the base station 100 to the first repeater 400 will be described.

The RF signal transmitted from the base station 100 is supplied to the RF signal processor 211, and the RF signal processor 211 filters, amplifies, and frequency converts the RF signal and supplies the RF signal to the all-optical converter 212. .

The all-optical converter 212 receiving the frequency-converted RF signal converts the RF signal into an optical signal, and the converted optical signal is supplied to the optical amplifier 214, and the optical amplifier 214 amplifies the optical signal. do.

The optical signal amplified by the optical amplifier 214 is supplied to the optical splitter 215, and the optical splitter 215 receiving the amplified optical signal distributes the amplified optical signal into a plurality of optical signals.

The divided optical signal is supplied to the optical branch coupling unit 216, and the optical branch coupling unit 216 couples and splits the distributed optical signal, and the combined branched optical signal is transmitted to the optical splitter 300 through the optical path. The optical splitter 300 transmits the optical signal transmitted through the optical path into a plurality of optical signals.

The distributed optical signal is supplied to the optical branch coupling unit 411 of the first repeater 400, and the optical branch coupling unit 411 couples and splits the distributed optical signal. To feed. The photoelectric converter 412 receiving the combined branched optical signal converts the optical signal into an electrical signal to output an RF signal, and the RF signal is supplied to the RF signal processor 413.

The RF signal processor 413 filters, amplifies, and frequency-converts the RF signal, and supplies the RF signal to the repeater 414 and transmits the RF signal to the called party's mobile terminal (not shown) through the antenna of the repeater 414.

On the other hand, the repeater 414 receiving the RF signal supplied from the called party's mobile terminal supplies the RF signal to the RF signal processor 413, and the RF signal processor 413 filters, amplifies and Frequency conversion.

The frequency-converted RF signal is supplied to the all-optical converter 415, which converts the RF signal into an optical signal, and the optical signal is supplied to the optical branch coupling unit 411. The branch combiner 411 combines and splits the optical signal, and the combined branched optical signal is transmitted to the optical splitter 300, and the optical splitter 300 distributes the optical signal into a plurality of optical signals.

The distributed optical signal is supplied to the optical branch coupling unit 216 of the hub 200 through an optical transmission path, and the optical branch coupling unit 216 branches after splitting and dividing the distributed optical signal. The optical signal is supplied to the photoelectric converter 213, and the photoelectric converter 213 receiving the branched optical signal converts the branched optical signal into an electrical signal and outputs an RF signal. The RF signal is an RF signal processor. Supplied to 211.

The RF signal processor 211 filters, amplifies, and frequency converts the RF signal and supplies the same to the base station 100.

As described above, in the optical relay system according to the present invention, by connecting a plurality of repeaters in series and / or in parallel to one hub using one optical path, the equipment cost of the optical path is minimized.

As described above, according to the present invention, since a plurality of repeaters installed to solve the base station and a radio wave shadow area are connected in series and / or parallel to one hub using an optical path, the installation cost of the plurality of repeaters can be reduced to a minimum. Since the hub and multiple repeaters are connected by one optical path, the installation cost of the optical path can be minimized. In addition, by receiving a plurality of sector signals from the base station variably distributes the signals among a plurality of repeaters, it is possible to utilize the base station resources to meet the needs of subscribers that vary in time and space.

In addition, although the present invention has been described in detail with reference to the embodiments described above, the present invention is not limited thereto, and modifications and improvements are possible within the scope of ordinary knowledge of those skilled in the art.

Claims (6)

A hub for converting the RF signal input from the base station into an optical signal and transmitting the optical signal in a forward direction, amplifying and branching the converted optical signal, and transmitting the branched optical signal through an optical path; An optical splitter for distributing an optical signal transmitted through the optical path; And It is connected in parallel and / or serially to the output side of the optical splitter, receives the divided optical signal and converts it into an RF signal, and transfers the converted RF signal to the user of the terminal through an antenna, the RF signal supplied from the user Receiving an antenna through an antenna and converting the signal into an optical signal, and transmitting the converted optical signal to a hub through an optical transmission path. The method of claim 1, wherein the hub An RF signal processor connected to an output side of the base station, for removing and amplifying an RF signal of a predetermined band among the RF signals, for filtering and amplifying signals transmitted from the plurality of repeaters and transmitting the filtered signal to the base station; An all-optical converter connected to an output side of the RF signal processing unit and converting the RF signal into an optical signal; A photoelectric converter connected to an input side of the RF signal processing unit and converting optical signals supplied from a plurality of repeaters into electrical signals; An optical amplifier connected to the output side of the all-optical converter and amplifying the optical signal; An optical splitter connected to an output side of the optical amplifier, for splitting the amplified optical signal into a plurality of optical signals; And And an optical branch coupling unit connected to an output side of the optical splitter, for coupling an optical signal output from the optical splitter, and for splitting an optical signal input through the optical path. The optical relay system of claim 2, wherein the all-optical converter is configured to convert the RF signal into an optical signal using a light emitting element. The optical relay system of claim 2, wherein the photoelectric converter is configured to convert the optical signal into an electrical signal using a light receiving element. The optical relay system of claim 2, wherein the optical branch coupling unit is provided to couple or branch an optical signal using an optical circulator. The optical relay system of claim 2, wherein the optical branch coupling unit is configured to couple or branch an optical signal using a wavelength division multiplexer.