KR20000073652A - Optical relay system in divergent join type - Google Patents

Abstract

PURPOSE: A branch-combined type optical relay system is provided to transmit transceiving signals to one optical cable to additionally connect an optical directional combiner to one remote main optical cable, so as to increase service relays, and to reduce installation costs, rental costs, and operating costs. CONSTITUTION: A link repeater synthesizes base station frequencies transmitted from base stations, and converts the base station frequencies into optical signals of each different optional wave to transmit the converted optical signals through one main optical cable. The link repeater generates and divides the transmitted optical signals, and transmits the optical signals to the base stations. Service repeaters receive signals transmitted from subscriber terminals to convert the signals into optical signals having optional waves, and transmit the converted optical signals to the link repeater through the main optical cable. The service repeaters generate the optical signals to transmit the generated optical signals to the subscriber terminals. Optical combiners connect the main optical cable for remote services and sub optical cables branched by the main optical cable, and connect the sub optical cables. The optical combiners connect the service repeaters with the main optical cable or connect the service repeaters with the sub optical cables to transmit bidirectional signals.

Description

Optical relay system in divergent join type

The present invention relates to an optical relay system, and in particular, a branch-coupled optical relay capable of transmitting a plurality of transmit / receive signals through one main optical cable, and expanding the repeater by connecting the main optical cable or a sub-optical cable branched therefrom as necessary. It's about the system.

Forward (base station to subscriber station) transmission of an optical relay system converts a signal transmitted from a base station into an optical signal, transmits it to a remote site via an optical cable, and then reproduces the signal and transmits it to the subscriber station. In the case of reverse transmission from the subscriber station to the base station, the signal is transmitted in the same manner as the forward direction.

However, in the conventional optical relay system, when there are several places where service relay is to be performed, the optical relay system is configured by laying several optical cables.

While such a conventional technology could satisfy the needs of subscribers, many inconveniences have been incurred to cover the facility costs, rents, and the like, which are added to the optical cable installation each time.

Accordingly, there is a need for the development of a branch-coupled optical relay system capable of transmitting a plurality of transmission / reception signals through one main optical cable and connecting the main optical cable or a sub-optical cable branched therefrom as necessary.

Accordingly, the present invention is to solve the above problems, the branch-coupled type that can be transmitted by transmitting a plurality of transmission and reception signals to one main optical cable, and connected to the main optical cable or the sub-optical cable branched therefrom as necessary An optical relay system is provided.

In the present invention for achieving the above object, in the mobile communication service system, the base station frequencies transmitted from the base station are synthesized and converted into optical signals of different arbitrary wavelengths and transmitted through one main optical cable, or the main optical cable The link relay means for reproducing and distributing the signal transmitted through the base station and transmitting the signal to the base station, and converts the signal transmitted from the subscriber station into an optical signal having an arbitrary wavelength and converts the signal to the link relay means through the main optical cable. A plurality of service relay means for transmitting or reproducing optical signals transmitted from the link relay means through the main optical cable to the subscriber terminal, and the one main optical cable and the main cable for service at a long distance. Connect a plurality of sub-optical cables branched from the optical cable, or It characterized in that it comprises a plurality of optical coupling means for transmitting the bidirectional signal by connecting the secondary optical cable, and connecting the plurality of the service relay means with one of the main optical cable or the secondary optical cable.

1 is a network diagram of a branch-coupled optical relay system according to the present invention;

2 is a configuration diagram of the link repeater of FIG. 1;

3 is a configuration diagram of the first service repeater of FIG. 1.

<Explanation of symbols for the main parts of the drawings>

A: base station B: link repeater

C _n : nth optical coupler D _n : nth service repeater

E _n : nth subscriber station

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

1 is a network diagram of a branch-coupled optical relay system according to the present invention.

In the service of mobile communication such as analog, digital, PCS, IMT 2000, WLL, etc., base station frequencies transmitted from base station A are synthesized and converted into optical signals of the same wavelength and transmitted through one main optical cable (thick solid line). Or, the link relay means (B) for reproducing and distributing the signal transmitted through the main optical cable and transmitting the signal to the base station, and transmitted by the local subscriber station (E1, E2, E3, E4, ..., En) Receives a signal and converts it into an optical signal having an arbitrary wavelength and transmits it to the link relay means through the main optical cable, or reproduces and transmits the optical signals transmitted from the link relay means through the main optical cable to the local subscriber station. Service relay means (D1, D2, D3, D4, ..., Dn) of the main light cable and a plurality of sub-optical cables branched from the main light cable so as to serve from a long distance A plurality of optical coupling means (C1) for connecting bidirectional signals or connecting the sub-optic cables to each other, and connecting a plurality of the service relay means with one main optical cable or connecting the sub-optical cable to transmit a bidirectional signal; A branch coupled optical relay system B, Cn, Dn is shown that includes C2, C3, C4, ..., Cn).

2 is a configuration diagram of the link repeater of FIG. 1, and FIG. 3 is a configuration diagram of the first service repeater of FIG. 1.

A forward communication service from a base station to a local subscriber station will be described with reference to the drawings.

1 and 2, the signals TX1, TX2, TX3, ..., TXn transmitted from the transmitter A1 of the base station A are synthesized by the synthesis amplifier 100 of the link repeater B. And amplified. The synthesized amplified signal is converted into an optical signal having different wavelengths by the high frequency photoconversion unit 110, and the influence of mutual interference is eliminated in the optical diplexer 120. The optical signal without the influence of mutual interference is transmitted through a single main optical cable (thick solid line) to a distant shaded area from several Km to several tens of Km.

1 and 3, the optical signal transmitted to the shadowed area is branched from the first optical combiner C1 to the first service repeater D1 or another optical combiner. The optical signal branched to the first service repeater D1 is passed through the first optical diplexer 200 and then reproduced and converted into a high frequency electric signal by the first photoelectric converter 210. The signal converted into the high frequency electric signal is amplified by the first low noise amplifier 220-1 to a high output and passes through the first diplexer 230. The signal from which the influence of mutual interference is removed from the first diplexer 230 is radiated from the antenna 240 to the first area subscriber station E1 in the shaded area.

On the other hand, the signal input to the other optical coupler is branched to the service repeater connected thereto or to the next optical coupler. The optical signal is reproduced in the same manner as that of the first service repeater D1, and the signal is transmitted to the local subscriber station. Here, the optical directional coupler (C4) or the service repeater (D4) has been shown to be connected to the sub-optic cable (thin solid line), which is separated from the main optical cable by a distance of several Km to several tens of Km.

Now, the case in which transmission from the local subscriber station to the base station will be described.

Signals RX1, RX2, RX3, RX4, ..., RXn transmitted in the reverse direction by the first local subscriber station E1 or other local subscriber stations E2, E3, E4, ..., En can be received. It is received at the antenna of the service repeater.

In the case of the RX1 signal transmitted by the first local subscriber station E1, it is received by the antenna 240 of the first service repeater E1 and passes through the first diplexer 230. The signal from which the influence of the mutual interference is removed in the first diplexer 230 is amplified by the first low noise amplifier 220-2 and converted into an optical signal having a constant wavelength by the first high frequency optical converter 250. The wavelength of the optical signal converted by the high frequency optical converter is different for each service repeater.

The converted optical signal is reverse-coupled at the optical directional coupler C1 through the same main optical cable (thick solid line) as the mutual interference is removed from the first optical diplexer 200 and forwarded.

The reverse coupling of the optical coupler receives the reverse transmission signals output from another service repeater, combines the signals, and outputs them to the next stage. Finally, it is output to the optical diplexer 120 of the link repeater (B).

The reverse-coupled optical signal is reproduced and converted by the photoelectric converter 130 into a high frequency electric signal through the optical diplexer 120 and distributed and amplified by the distribution amplifier 140. The distributed amplified RX1 signal is transmitted to the receiver A2 of the base station A.

RX2, RX3, RX4, ..., RXn signals transmitted from other service repeaters as described above are also transmitted to the receiver A2 of the base station A through the same process. Therefore, high frequency TX1, TX2, TX3, TX4, ..., TXn and RX1, RX2, RX3, RX4, ..., RXn signals, that is, a plurality of transmit and receive signals are transmitted through one main optical cable. And it will relay the two-way communication supporting the forward communication service from the base station to the local subscriber station and the reverse communication service from the local subscriber station to the base station at the same time.

If the branch cable from the optical directional coupler C2 to the service repeaters D2 and D4 is long, an additional directional coupler C4 is added, and the service relays D2 and D4 are connected to the optical directional coupler C4. It can also be connected by (thin solid line). In other words, in order to expand the service relay area, another optical directional coupler is branched from one main or sub-optical cable into a tree structure so that it can be relayed to a shadow area several Km to several tens of Km away from the base station. It is also possible to connect the optical coupler with at least one service repeater.

In another embodiment of the present invention, when the number of service repeaters is small (for example, 2 to 3), an optical signal having the same wavelength when converting a signal transmitted by a local subscriber station into an optical signal having an arbitrary wavelength You can also convert to.

The present invention is not limited by the embodiments described above, and various changes and modifications can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

As described above, the present invention can transmit a plurality of transmission and reception signals through one optical cable even when there are several service repeaters.

Further, by additionally connecting the optical directional coupler to one long distance optical fiber cable, it is easy to expand the service repeater, and it is possible to meet the service needs of subscribers.

In addition, fiber cable installations, rent and operating costs are significantly reduced.

Claims (7)

In the mobile communication service system, For link which synthesizes base station frequencies transmitted from base station and converts them into optical signals of different arbitrary wavelengths and transmits them through one main fiber cable, or reproduces and distributes the signals transmitted through the main fiber cables and transmits them to the base station Relay means; Receives the signal transmitted by the subscriber station and converts it into an optical signal having an arbitrary wavelength and transmits it to the link relay means through the main optical cable, or the optical signals transmitted from the link relay means through the main optical cable. A plurality of service relay means for reproducing and transmitting to the subscriber station; Connecting one of the main optical cables and the sub-optical cables branched from the main optical cables to a plurality of the main optical cables, or connecting the sub-optical cables to each other, and connecting the plurality of service relay means to the single main optical cable And a plurality of optical coupling means for transmitting bidirectional signals in connection with the negative optical cable. The branch coupling type optical relay as claimed in claim 1, wherein the service relaying means converts the signal transmitted from the subscriber station into an optical signal having a different wavelength when each signal is converted into an optical signal having an arbitrary wavelength. system. The method of claim 1, wherein each of the relay means is a branch-coupled type, characterized in that for relaying the bidirectional communication at the same time supporting the forward communication service from the base station to the subscriber station and the reverse communication service from the subscriber station to the base station; Optical relay system. The branch coupling type optical relay system according to claim 1, wherein the link relay means and the plurality of service relay means transmit a plurality of transmit and receive signals through one main optical cable. The branch coupling type optical relay system according to claim 1, wherein another optical coupling means is branched from one main optical cable or the secondary optical cable in a tree structure to extend a service relay area. 2. The branch coupling type optical relay system according to claim 1, wherein each of the optical coupling means can be connected with at least one of the service relay means. The branch coupling type optical relay system according to claim 1, wherein the service relay means converts the signal transmitted from the subscriber station into an optical signal having the same wavelength when each signal is converted into an optical signal having an arbitrary wavelength. .