KR100350913B1 - Multi-drop optic repeating system - Google Patents

Abstract

The present invention relates to a multi-branch type optical relay device used to eliminate service shadow areas in a code division multiple access (CDMA) mobile communication system. The main relay device (Master) that transmits and receives radio signals and the secondary slave device (Slave) that transmits and receives radio signals to and from the mobile terminal are connected by using an optical line to service the shadow area, but a special type of shadow formed in the longitudinal direction In order to service the area, there was a disadvantage in that a plurality of main relays and sub relays had to be installed.

The present invention has been made to solve the above problems, by connecting a plurality of secondary repeaters to one main relay device, such that the shaded areas such as mountain areas, amusement parks, highways, etc. are irregularly adjacent or formed in the longitudinal direction. Provides a multi-branch optical repeater that can effectively solve the special shaded area.

Description

Multi-branch optical repeater

The present invention relates to a multi-branch optical relay device used to eliminate service shadow areas in a CD-based mobile communication system. More specifically, the present invention relates to a multi-branch optical relay device in a single master unit. Multi-branch optical repeater that can effectively solve the special type of shading area where the shading area is irregularly adjacent or formed in the length direction such as mountain area, amusement park, highway, etc. by connecting to the slave unit It is about.

In the field of the present invention, an optical relay apparatus according to the prior art services a shadow area by connecting a main relay apparatus for transmitting and receiving a radio signal with a base station and a secondary relay apparatus for transmitting and receiving a radio signal with a mobile terminal using an optical line. However, in order to service a special shape of the shaded area formed in the longitudinal direction, there was a problem in that a plurality of primary relays and secondary relays had to be installed.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, and the optical relay device according to the prior art uses an optical signal to solve the problem that only one main relay and one secondary relay are used. It is a device that relays radio waves in both directions between base station and mobile terminal by using multiple main relays in one main relay system, so that service area can be extended and shaded area such as mountain area, amusement park, highway, etc. It is a technical object of the present invention to provide a multi-branch type optical repeater capable of effectively eliminating a specially shaped shadow area that is irregularly adjacent or formed in the longitudinal direction.

1 is a block diagram showing a multi-branch optical relay device according to the present invention.

Figure 2a is a block diagram showing a main relay device of the multi-branch optical relay device according to the present invention.

Figure 2b is a block diagram showing another embodiment of the main relay of the multi-branch optical relay in accordance with the present invention.

3 is a block diagram showing a first secondary relay of the multi-branch optical relay according to the present invention;

4 is a block diagram showing a second secondary relay of the multi-branch optical relay according to the present invention;

Fig. 5 is a block diagram showing a third secondary relay of the multi-branch optical relay in accordance with the present invention.

6 is an external perspective view of the main relay unit and the sub-relay unit showing an embodiment of the multi-branch optical relay device according to the present invention.

Figure 7 is an installation diagram showing an embodiment of a multi-branch optical relay device according to the present invention.

* Explanation of symbols for the main parts of the drawings

111, 61, 713: main relay 112,123: optical module

113, 124, 215, 312, 411, 424, 512: wavelength division multiplexer

114, 126, 2l4, 323, 421, 426, 523: Electro-optical converter

115, 125, 216, 313, 412, 513: opto-electric converter

116, 222, 324, 425, 511, 714: optical line 121, 715: first secondary repeater

122, 311, 422: optocouplers 127, 317, 416, 517: duplexer

128, 318, 417, 518: antenna 131, 717: second secondary relay

132, 423: amplifying means 141: n-th relay

211, 217, 219, 220, 314, 514, 522: 2-path divider

212, 320, 326, 419, 429, 520, 525: low noise amplifier

213, 322, 427: two-path synthesizer 218: up converter

221, 321, 420, 521: drive amplifiers 223, 329, 432, 528: band pass filter

224: Isolator 315, 414, 515: Preamplifier

316, 415, 516: high power amplifier

319, 327, 418, 430, 519, 526: Directional Coupler

325, 428, 524: down converters 328, 431, 527: diversity antenna

413: three-path distributor 62: secondary repeater

711: base station 712: base station service area

716: first shaded area 718: second shaded area

719: third secondary relay 720: third shaded area

In order to solve the above technical problem, the multi-branched optical relay device according to the present invention includes a main relay device for transmitting and receiving a radio signal with a base station, a plurality of secondary relay devices for transmitting and receiving radio signals with a mobile terminal, a radio signal and an optical signal. All-optical and optical-to-electric converters for converting each other, wavelength division multiplexers for multiple access of optical signals, optical lines for connecting primary and secondary repeaters, and optical couplers for expanding secondary repeaters Include.

Hereinafter, an embodiment of a multi-branch optical relay device according to the present invention will be described with reference to the accompanying drawings. 1 is a block diagram illustrating a multi-branch optical relay device according to the present invention, which includes an optical module 112 including an all-optical converter 114, a wavelength division multiplexer 113, and an opto-electric converter 115. The main relay 111 is connected to the first sub relay 121 by an optical line 116. The first secondary repeater, like the main repeater, includes an opto-electric converter 125, a wavelength division multiplexer 124, and an all-optical converter 126, and is duplexer 127 from the base station. The radio signal to the mobile terminal and the radio signal from the mobile terminal to the base station are combined and transmitted and received through the antenna 128. In addition, an optical signal is properly distributed by the optical coupler 122 provided between the main relay and the first secondary relay, and is connected to the second secondary relay 131 through an optical line. By allowing the optical signal distributed from the secondary relay device of 2 to be connected to the next secondary relay device, it is possible to extend to the nth secondary relay device 141.

FIG. 2A is a block diagram illustrating a main relay of a multi-branch optical relay according to the present invention, wherein a wireless signal input from a base station (not shown) passes through a two-path divider 211 through a low noise amplifier 212. It is properly amplified, synthesized with a local oscillator signal output from the up converter 218 by the two-path synthesizer 213, and wirelessly transmitted by the electro-optical converter 214. The signal is converted into an optical signal having a wavelength of [lambda] o. The optical signal thus converted is transmitted by the optical line 222 through a wavelength division multiplexing (WDM) 215. On the contrary, the optical signal input from the mobile terminal to the secondary relay (not shown) and transmitted by the optical line 222 is a signal having a wavelength of λ ₁ and passes through the wavelength division multiplexer 215. 214 converts the optical signal into a wireless signal, which is amplified by the drive amplifier 221 via a two-path divider 217 and delivered to the base station. In this case, in FIG. 2A, a band pass filter 223 for passing only a wireless signal received from a mobile terminal is provided between two two-path dividers 211 and 220, and one two-path divider 211 connects a transmission / reception signal to a base station. The other two-path distributor 220 is used to monitor the radio signal received from the terminal. This improves the isolation characteristics between the transmitted signal and the received signal, thereby reducing the noise of the system and suppressing spurious.

Figure 2b is a block diagram showing another embodiment of the main repeater of the multi-branch optical repeater according to the present invention is provided with an isolator 224 between the two two-path divider (211, 220) by the radio signal in one direction Since only the pass is achieved, the same effects as those obtained by the band pass filter 223 in FIG. 2A can be obtained, and the insertion loss can be lowered.

3 is a block diagram showing a first secondary relay of the multi-branch optical relay according to the present invention. As described in FIG. 2, the optical signal having a wavelength λ ₀ transmitted from the main relay through the optical line is converted into a wireless signal by the photoelectric converter 313 through the wavelength division multiplexer 312. The wireless signal is amplified by a preamplifier 315 and a high power amplifier (HPA) 316 via a two-path divider 314 and transmitted to the duplexer 317. The duplexer combines the transmission signal and the reception signal in one path, and the signal passing through the duplexer is sent out to the space by the antenna 318. In addition, the received signal from the mobile terminal introduced into the antenna is separated through the duplexer 317 to minimize the noise of the system by the low noise amplifier 320 and amplified to an appropriate level by the drive amplifier 321 and the two-path synthesizer Via 322, the radio signal is converted into an optical signal having a wavelength of λ ₁ via an all-optical converter 323. The optical signal thus converted is transmitted to the main relay by an optical line through the wavelength division multiplexer 312. In addition, in the diversity path illustrated in FIG. 3, the frequency introduced by the diversity antenna 328 is down-converted in the down converter 325 via the low noise amplifier 326 (in this embodiment, 70 MHz is used). The converted wireless signal passes through the two-path synthesizer 322 and is converted into an optical signal by the all-optical converter 323 and transmitted by the optical line through the wavelength division multiplexer 312 to the main relay device. In this case, in order to obtain the diversity effect by receiving the same signal to the antenna 318 by the main path and the diversity antenna 328 by the diversity path, radio of the diversity path is avoided. After the down-frequency conversion of the signal is converted into the original radio signal by the up-converter 218 in the main relay is output to the base station diversity port.

In addition, in FIG. 3, the optical signal transmitted from the main relay is controlled by the optical coupler 311 in accordance with an appropriate ratio (3: 7 in this embodiment). (Not shown), the ratio varies depending on the length of the optical path. 4 is a block diagram showing a second secondary relay of the multi-branched optical relay according to the present invention, which is distributed by the optical coupler and connected to the first secondary relay by an optical line, The path for transmitting the signal is basically similar to that in FIG. 3, such as wavelength division multiplexer 411, opto-electric converter 412, three-path divider 413, preamplifier 414, high power amplifier 415, duplexer. It passes through 416 in turn and is sent out to space by the antenna 417. Similarly, the signal from the mobile terminal introduced into the antenna 417 is the duplexer 416, the low noise amplifier 419, the drive amplifier 420, the two-path synthesizer 427, the all-optical converter 421, the wavelength division. The signal transmitted through the diversity antenna 431 is transmitted to the path of the medium stage 411, and the signal introduced through the diversity antenna 431 is transmitted to the low noise medium amplifier 429, the down converter 428, the two-path synthesizer 427, and all-optical light. Transducer 421 is routed to the path of wavelength division multiplexer 411. In this case, the wavelength of the optical signal is λ _o from the main relay and λ ₂ from the mobile terminal.

In addition, the second secondary relay has the following components for connecting the third secondary relay. As can be seen in Figure 4, the optical signal input to the second sub-relay is used to compensate for the loss without using the optical coupler 122,311 as in the first sub-relay. Is converted into an optical signal using an all-optical converter 426 and a wavelength division multiplexer 424. Then, it is transmitted to the third secondary repeater through the optical line 425.

FIG. 5 is a block diagram illustrating a third secondary repeater of the multi-branch optical relay according to the present invention, except for the optical coupler 311 in FIG. Since the operation principle of relaying the signal path and the diversity path from the terminal is also the same as that of FIG. 3, detailed description thereof will be omitted. Also in this case, the wavelength of the optical signal is lambda o from the main relay and lambda ₃ from the mobile terminal.

6 is an external perspective view of a main relay unit and a sub-relay device showing an embodiment of the multi-branch optical relay device according to the present invention, and FIG. 7 is a view showing an embodiment of the multi-branch optical relay device according to the present invention. Installation diagram. In FIG. 6, only one secondary relay 62 is shown for one primary relay 61. However, since the secondary relays may be increased in number as shown in FIG. 7, the base station 711 is an example. When there are a plurality of radio shadow areas in the adjacent area of the serving base station service area 712, the first shadow area by the first secondary relay device 715 by installing the multi-branched optical relay device according to the present invention. 716, a second shadowed area 718 by a second secondary relay 717, and a third shadowed area 720 by a third secondary relay 719. Service will eliminate the entire shadow area.

The present invention relates to a multi-branch type optical relay device used to eliminate service shadow areas in a CD-based mobile communication system, and allows a plurality of secondary relay devices to be connected to one main relay device in a mountain area. It has the effect of effectively eliminating the special shape of the shaded areas where the shaded areas are irregularly adjacent or formed in the length direction such as the amusement park, highway, etc.

Claims (6)

In the relay device for eliminating the radio shadow area of the wireless communication system, A main relay device for transmitting and receiving a radio signal with a base station, A plurality of secondary repeaters for transmitting and receiving a wireless signal with a mobile terminal, An all-optical converter that converts a wireless signal into an optical signal, A photoelectric converter for converting an optical signal into a wireless signal; A wavelength division multiplexer for multiplexing a plurality of optical signals having a plurality of wavelengths, Optical line for connecting main relay and secondary relay Multi-branch optical repeater comprising an optical coupler for expanding the secondary repeater. The method of claim 1, wherein the main relay device, And a band pass filter (223) between the transmission path and the reception path between the base station and the base station to increase the separation between transmission and reception signals. The method of claim 1, wherein the main relay device, The multi-branched optical relay device comprising an isolator (224) between the transmission path and the reception path with the base station to increase the separation between the transmission and reception signals by one. The method of claim 1, By providing the optical signal distribution means in the first sub-relay connected to the main relay, the sub-relay can be expanded by distributing the optical signal from the first sub-relay. Device. The method of claim 1, The second secondary relay connected to the first secondary relay includes a distribution means consisting of a low noise amplifier 423 and an all-optical converter 426 to compensate for the loss caused by the optical line to expand the secondary relay. Multi-branch optical repeater, characterized in that. The method of claim 1, Multi-branch optical repeater, characterized in that the downlink signal from the base station and the uplink signal from the terminal using different optical wavelengths, but using a single optical line by having a wavelength division multiplexer in the main relay and the secondary repeater .