KR100337223B1 - Method and system of optical-repeating for muti-frequency bands - Google Patents

Abstract

Disclosed are a multi-frequency band optical relay apparatus and method capable of simultaneously relaying mobile communication service systems having different frequency bands. The apparatus consists of an optical repeater mother station and an optical repeater station linked by an optical cable. The optical relay station converts the frequency of the IMT-2000 forward communication signals, synthesizes the IS-95A, IS-95B, or IS-95C forward communication signals and the frequency-converted IMT-2000 forward communication signals through the optical cable. Transmit to repeater station. The repeater mother station classifies the reverse synthesized signal inputted through the optical cable according to the frequency band and frequency converts the classified reverse communications, and the reverse communications of the IMT-2000 and the IS-95A, IS-95B, and IS- Generate each of the 95C reverse communication signals. The repeater station classifies the forward synthesized signal inputted through the optical cable according to the frequency band and frequency converts the classified IMT-2000 forward communication signals to forward communications of the IMT-2000 and IS-95A, IS-95B, or Transmit IS-95C forward communication signals. The repeater station frequency converts the IMT-2000 reverse communication signals received through the antenna to synthesize the reversed communication signals of the frequency-converted IMT-2000 and the reverse communication signals of IS-95A, IS-95B, or IS-95C. To the optical repeater home station. Therefore, by converting and transmitting the IMT-2000 frequency, which is a frequency of 2 GHz or more to 2 GHz or less, it is possible to utilize an optical module installed.

Description

Multi-frequency band optical relay device and method {Method and system of optical-repeating for muti-frequency bands}

The present invention relates to a mobile communication relay apparatus and a method thereof, and more particularly, to a multi-frequency band optical relay apparatus and method capable of simultaneously serving mobile communication service systems having different frequency bands.

Due to the rapid development of digital technology, the mobile communication service has been rapidly developed from the analog method all over the world, including GSM service in Europe and mobile communication service using CDMA technology in Korea. As a result, the wireless network field is being integrated into IMT-2000 (FPLMTS, Future Public Land Mobile Telecommunication System).

IMT-2000 will use the entire 230 MHz frequency band globally under 1.885-2.025 GHz and 2.110-2.200 GHz under Radio Regulations Article 736A. The Ministry of Information and Communication will present the IMT-2000 standard and then select operators to commercialize the IMT-2000 service.

Mobile communication systems are using relay systems for frequency reuse, coverage expansion, and shading. In particular, the optical relay device currently used in the mobile communication system is designed to transmit a frequency signal of 2 GHz or less, there is a problem in relaying the signal of the IMT-2000, that is, the frequency band of 2 GHz or more.

Therefore, there is a need to find a way to relay not only the current IS-95A, IS-95C, and IS-95B but also IMT-2000 communication signals by utilizing the existing optical cables and optical modules.

Accordingly, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a multi-frequency optical relay apparatus and method capable of relaying a frequency of 2 GHz or more through existing optical cables and optical modules.

According to a first aspect of the present invention for achieving the above object, a multi-frequency band forward signal optical relay device includes means for converting a frequency of each of one or more forward communication signals of the IMT-2000; Means for synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the forwarded communication signals of the frequency converted one or more IMT-2000; Means for converting the forward synthesized signal generated by the combining means into an optical signal and transmitting it through an optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing forward synthesized signals from said converting means according to frequency bands; Means for frequency converting forward communications of one or more IMT-2000s distributed by the distribution means; And one or more signals of one or more forward communications of the IMT-2000 frequency-converted by the frequency converting means and the forward communication signals of the IS-95A, IS-95B, and IS-95C by the converting means. And means for transmitting each.

In the multi-frequency band reverse signal optical relay device according to the second aspect of the present invention, one or more reverse communication signals of IMT-2000 and reverse direction of IS-95A, IS-95B, or IS-95C are received through an antenna. Means for converting a frequency of each of at least one or more of the communication signals; Means for synthesizing the reverse signals converted by the frequency converting means; Means for converting the reverse synthesized signal synthesized by the combining means into an optical signal and transmitting the optical signal through an optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing the reverse forward composite signal converted by the conversion means according to a frequency band; And frequency converting each of the reverse communications distributed by the distributing means, so that one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C. And means for generating the above signals, respectively.

An optical repeater in a multi-frequency band according to a third aspect of the present invention is composed of an optical repeater mother station and an optical repeater station linked by an optical cable, and the optical repeater main station comprises one or more forward communication signals of IMT-2000. Means for converting each of the frequencies; Means for synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the forwarded communication signals of the frequency converted one or more IMT-2000; Means for converting the forward synthesized signal generated by the synthesizing means into an optical signal and transmitting it through the optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing a reverse forward composite signal from the conversion means according to a frequency band; And frequency converting each of the reverse communications distributed by the distributing means, so that one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C. Means for generating each of the above signals, the optical repeater markings comprising: means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing a forward synthesized signal from the converting means according to a frequency band; Means for frequency converting forward communications of one or more IMT-2000s distributed by the distribution means; One or more of forward communications of one or more IMT-2000s frequency-converted by the frequency converting means and one or more of forward communications signals of the IS-95A, IS-95B, and IS-95C by the converting means, respectively. Means for transmitting; For converting a frequency of each of one or more reverse communication signals of IMT-2000 and at least one or more of the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; Way; Means for synthesizing the reverse signals converted by the frequency converting means; And means for converting the backward synthesized signal synthesized by the combining means into an optical signal and transmitting the optical signal.

According to a fourth aspect of the present invention, a method for forwarding a signal in a multiple frequency band includes: a) converting a frequency of each of the one or more forward communication signals of the IMT-2000; b) synthesizing one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the frequency converted one or more forward communication signals of IMT-2000; c) converting the forward synthesized signal of step b) into an optical signal and transmitting it through an optical cable; d) converting an optical signal input through the optical cable into an electrical signal; e) distributing the forward synthesized signal according to step d) according to the frequency band; f) frequency converting one or more forward communications of the IMT-2000 according to step e); And g) one or more signals of the frequency-converted one or more of the IMT-2000 forward-transformed by step f) and one or more of the forward communication signals of the IS-95A, IS-95B, and IS-95C by step d), respectively. Transmitting step.

In the multi-frequency band reverse signal optical relay method according to the fifth aspect of the present invention, a) one or more reverse communication signals of IMT-2000 received through an antenna and a reverse direction of IS-95A, IS-95B, or IS-95C Converting a frequency of each of one or more of the communication signals; b) synthesizing the reverse signals converted by step a); c) converting the backward synthesized signal synthesized in step b) into an optical signal and transmitting it through an optical cable; d) converting an optical signal input through the optical cable into an electrical signal; e) distributing the inverse forward composite signal converted by step d) according to the frequency band; And f) frequency converting each of the reverse communications distributed by step e), such that one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C. Or generating each of the more signals.

A multi-frequency optical relay method according to a sixth aspect of the present invention comprises the steps of: a) converting a frequency of each of the one or more forward communication signals of the IMT-2000; b) synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the frequency converted one or more forward communication signals of IMT-2000; c) converting the forward synthesized signal generated by step b) into an optical signal to generate a forward optical signal, and transmitting the generated forward optical signal through the optical cable; d) converting a reverse optical signal input through the optical cable into an electrical signal; e) distributing the backward synthesized signal from step d) according to the frequency band; f) frequency converting each of the reverse communications distributed by step e) to perform one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C; or Generating each of the more signals; g) converting a forward optical signal input through the optical cable into an electrical signal; h) distributing the forward synthesized signal according to step g) according to the frequency band; i) frequency converting one or more forward communications of the IMT-2000 distributed by step h); j) transmitting one or more of the forward communications of the one or more IMT-2000s and the forward communications signals of the IS-95A, IS-95B, and IS-95C, respectively, frequency-converted by step i); k) converts a frequency of each of one or more reverse communication signals of one or more IMT-2000s and at least one or more of the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; Doing; l) synthesizing the reverse signals converted by step k); And m) converting the backward synthesized signal synthesized in step l) into an optical signal and transmitting it through an optical cable.

According to the present invention, it is possible to relay not only the current IS-95A, IS-95C, IS-95B, but also IMT-2000 communication signals by utilizing the currently constructed optical cable and optical module. By utilizing the existing mobile communication system to the maximum, it is possible to reduce the equipment cost for the new communication service.

1 is a diagram illustrating an optical repeater home station of a multi-frequency band optical repeater according to an exemplary embodiment of the present invention.

2 is a diagram illustrating an optical repeater trace of a multi-frequency band optical repeater according to an exemplary embodiment of the present invention.

3 is a flowchart illustrating a relay operation of a forward communication signal of the multi-frequency band optical relay shown in FIGS. 1 and 2.

4 is a flowchart illustrating a relay operation of a reverse communication signal of the multi-frequency band optical relay shown in FIGS. 1 and 2.

<Explanation of symbols for main parts of drawing>

100: optical repeater home station 120: first forward transmission unit

121, 122, 123, 226, 227: Preamplifier / Attenuator

124, 143, 144, 145, 225, 249, 250, 251: frequency converter

125, 126, 223, 224: filter 128, 253: E / O converter

140: first reverse receiver 141, 221: O / E converter

142, 222: distributor 146, 147, 148, 149: amplifier / attenuator

200: optical repeater mark 220: second forward transmitter

240: second reverse receiver 229, 230, 231: amplifier

232, 233, 234, 241, 242, 243, 244: band filter

245, 246, 247, 248: low noise amplifier

127, 252: second synthesizer

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

1 is a diagram illustrating an optical repeater mother station 100 of a multi-frequency band optical relay device according to an embodiment of the present invention.

2 is a diagram illustrating an optical repeater mark 200 of a multi-frequency band optical repeater according to an embodiment of the present invention.

1 and 2, a multi-frequency band optical repeater according to the present invention is composed of an optical repeater mother station 100 and an optical repeater mark 200 linked by an optical cable.

Preferably, the optical repeater main station is composed of a first forward transmitter 120 and a first reverse receiver 140, as shown in FIG.

The first forward transmission unit 120 is a forward communication signal of the IS-95A, IS-95B, or IS-95C from the IS-95A, IS-95B, or IS-95C base station 300 and the IMT-2000. The IMT-2000 forward communication signals from the base station 400 are synthesized to generate a forward synthesized signal, and the forward synthesized signal is provided to the optical relay station 200.

Preferably, the first forward transmitter 120 includes first to third preamplifiers / attenuators 121 to 123, first frequency converter 124, first and second filters 125 and 126, and One E / O converter 128.

The first to third preamplifiers / attenuators 121 to 123 are IS-95A, IS- from the IS-95A, IS-95B, or IS-95C base station 300, as shown in FIG. Amplify and attenuate forward communication signals of 95B, or IS-95C and IMT-2000 forward communication signals from the IMT-2000 base station 400, respectively, the amplified and attenuated IS-95A, IS-95B, or Forward communication signals of the IS-95C are provided to the first filter 125 and the amplified and attenuated IMT-2000 forward communication signals are provided to the first frequency converter 124.

The first frequency converter 124 frequency converts each of the IMT-2000 forward communication signals from the second and third preamplifiers / attenuators 122 and 123, and each of the converted IMT-2000 forward communication signals. Is provided to the second filter 126. Advantageously, the first frequency converter 124 converts the IMT-2000 forward communication signals to a frequency of 2 GHz or less.

The first and second filters 125 and 126 are IS-95A, IS-95B, or IS-95C forward communication signals from the first preamplifier / attenuator 121 and the first frequency converter 124. Filter each of the IMT-2000 forward communications signals from &lt; RTI ID = 0.0 &gt;) &lt; / RTI &gt;

The first synthesizer 127 is configured to forward forward communications signals of IS-95A, IS-95B, or IS-95C from the first filter 125 and the frequency-converted IMT- from the second filter 126. 2000 forward communication signals are synthesized to generate a forward synthesized signal, and the generated forward synthesized signal is provided to the first E / O converter 128.

The first E / O converter 128 converts the forward synthesized signal from the first synthesizer 127 into an optical signal and transmits it to the optical repeater tracing 200 through an optical cable.

The first reverse receiving unit 140 transmits the reverse synthesized signal from the optical repeater station 200 according to the frequency band, IS-95A, IS-95B, or IS-95C reverse communication signals and IMT-2000 reverse communication signals. Respectively detect and detect the detected IS-95A, IS-95B, or IS-95C reverse communication signals and IMT-2000 reverse communication signals from the IS-95A, IS-95B, or IS-95C base station 300; Provided to the IMT-2000 base station 400, respectively.

Preferably, the first reverse receiver 140 includes a first O / E converter 141, a first divider 142, second to fourth frequency converters 143 to 145, and first to fourth amplifiers. / Attenuators 146-149.

The first O / E converter 141 converts an optical signal input through the optical cable into an electrical signal to generate a reverse communication signal, and provides the generated reverse communication signal to the first distributor 142. do.

The first distributor 142 distributes the reverse communication signal from the first O / E converter 141 according to a frequency band to reverse communication signals of the IMT-2000 and the IS-95A, IS-95B, and IS. Generating a reverse communication signal of -95C, respectively, and providing the generated reverse communication signals of the IMT-2000 to the second to fourth frequency converters 143 to 145, respectively, the IS-95A, IS-95B, and The reverse communication signals of the IS-95C are provided to the first amplifier / attenuator 146.

The second frequency converter 143 frequency converts reverse communication signals of IS-95A, IS-95B, and IS-95C from the first distributor 142, and converts the frequency-converted IS-95A, IS-95B, And reverse communication signals of IS-95C to the second amplifier / attenuator 147, respectively.

Each of the third and fourth frequency converters 144 and 145 performs frequency conversion on each of the reverse communication signals of the IMT-2000, and converts the frequency-converted reverse communication signals of the IMT-2000 as shown in FIG. To third and fourth amplifiers / attenuators 148 and 149, respectively.

The first and second amplifiers / attenuators 146 and 147 are configured to transmit reverse communication signals of IS-95A, IS-95B, and IS-95C from the first divider 142 and the first frequency converter 143. Amplification and attenuation are provided to the IS-95A, IS-95B, or IS-95C base station 300.

The third and fourth amplifiers / attenuators 148 and 149 amplify and attenuate reverse communication signals of the IMT-2000 from the third and fourth frequency converters 144 and 145, respectively, so as to amplify and attenuate the IMT-2000 base station. 400).

As shown in FIG. 2, the optical relay station 200 includes a second forward transmitter 220 and a second reverse receiver 240.

The second forward transmitter 220 detects forward communications of IMT-2000 and forward communications signals of IS-95A, IS-95B, and IS-95C in a frequency band using a forward synthesized signal input through an optical cable. The detected forward communications of the IMT-2000 and the forward communications signals of the IS-95A, IS-95B, and IS-95C are transmitted through an antenna.

Preferably, the second forward transmitter 220 includes a second O / E converter 221, a second distributor 222, third and fourth filters 223 and 224, a fifth frequency converter 225, Fourth to sixth pre-amplifiers / attenuators 226 to 228, first to third amplifiers 229 to 231, and first to third band filters 232 to 234.

The second O / E converter 221 converts an optical signal input through the optical cable into an electrical signal.

The second divider 222 forwards the forward synthesized signal from the second O / E converter 221 according to the frequency band and forward communication signals of the IS-95A, IS-95B, and IS-95C and the IMT-2000. Forward communications of the IS-95A, IS-95B, and IS-95C, and forward the detected IMT-2000 forward communications to the third and fourth filters 223 and 224, respectively. To distribute.

The third filter 223 filters noise from the forward communication signals of the IS-95A, IS-95B, and IS-95C, and filters the forward communication signals of the IS-95A, IS-95B, and IS-95C. To the fourth preamplifier / attenuator 226.

The fourth preamplifier / attenuator 226 amplifies / attenuates forward communication signals of the IS-95A, IS-95B, and IS-95C, and the amplified / attenuated IS-95A, IS-95B, and IS- Provide 95C forward communication signals to the first amplifier 229.

Then, the first amplifier 229 transmits forward communication signals of the IS-95A, IS-95B, and IS-95C through the first band filter 232 and the antenna.

The fourth filter 224 filters the IMT-2000 forward communications and provides the filtered IMT-2000 forward communications to the fifth frequency converter 225.

The fifth frequency converter 225 frequency-converts IMT-2000 forward communications from the fourth filter 224 according to its frequency, and converts the frequency-converted IMT-2000 forward communications into fifth and sixth preamplifier / attenuators. 227 and 228, respectively.

The fifth and sixth preamplifier / attenuators 227 and 228 amplify / attenuate the IMT-2000 forward communications from the fifth frequency converter 225, and cancel the amplified / attenuated IMT-2000 forward communications. To the second and third amplifiers 230 and 231.

The IMT-2000 forward communications provided to the second and third amplifiers 230 and 231 are amplified by the second and third amplifiers 230 and 231, and the second and third band filters 233 and 234. Is sent externally).

The second reverse receiver 240 converts one or more reverse communication signals of one or more IMT-2000s and reverse communication signals of IS-95A, IS-95B, or IS-95C received through an antenna into optical signals. Transmit to the optical repeater home station via cable.

Preferably, the second reverse receiver 240 includes fourth to seventh band filters 241 to 244, first to fourth low noise amplifiers 245 to 248, and sixth to eighth frequency converters 249 to 251. ), A second synthesizer 252, and a second E / O converter 253.

The fourth to seventh band filters 241 to 244 include one or more reverse communication signals of one or more IMT-2000 and reverse communication signals of IS-95A, IS-95B, or IS-95C received through the antenna. To the first to fourth low noise amplifiers 245 to 248 for detecting the signals according to frequency and providing the detected reverse communication signals of IMT-2000 and reverse communication signals of IS-95A, IS-95B, or IS-95C. do.

The first to fourth low noise amplifiers 245 to 248 are reverse communication signals of the IMT-2000 and the IS-95A, IS-95B, or IS- from the fourth to seventh band filters 241 to 244. Low noise amplification of 95C reverse communication signals, reverse communication signals of low noise amplified IMT-2000 and reverse communication signals of IS-95A, IS-95B, or IS-95C. To provide.

The sixth to eighth frequency converters 249 to 251 frequency convert the reverse communication signals of the IMT-2000 and the reverse communication signals of IS-95A, IS-95B, or IS-95C, and convert the frequency-converted IMT-. Provide reverse communication signals of 2000 and reverse communication signals of IS-95A, IS-95B, or IS-95C to the second synthesizer 252.

The second synthesizer 252 synthesizes the reversed communication signals of the frequency-converted IMT-2000 and the reverse communication signals of IS-95A, IS-95B, or IS-95C to generate the reverse synthesized signal. The reverse synthesized signal is provided to the second E / O converter 253.

Then, the second E / O converter 253 converts the backward composite signal into an optical signal and transmits the reverse signal to the optical repeater main station 100 through an optical cable.

Hereinafter, an operation of a multi-frequency band optical relay device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a flowchart illustrating a relay operation of a forward communication signal of the multi-frequency band optical relay shown in FIGS. 1 and 2.

4 is a flowchart illustrating a relay operation of a reverse communication signal of the multi-frequency band optical relay shown in FIGS. 1 and 2.

First, a process of relaying a forward communication signal will be described with reference to FIG. 3.

Forward communication signals of IS-95A, IS-95B, or IS-95C from the IS-95A, IS-95B, or IS-95C base station 300 and IMT-2000 from IMT-2000 base station 400 When forward communication signals are input to the first forward transmitter 120, the forward communication signals of the IS-95A, IS-95B, or IS-95C and the IMT-2000 forward communication signals are the first forward transmitter 120. Are amplified and attenuated by first to third preamplifiers / attenuators 121 to 123, respectively. Forward communication signals of IS-95A, IS-95B, or IS-95C amplified and attenuated by the first preamplifier / attenuator 121 are provided to the first filter 125, and the second and third The IMT-2000 forward communication signals amplified and attenuated by the preamplifiers / attenuators 122 and 123 are frequency-converted by the first frequency converter 124 into low-frequency signals (S11).

The forward communication signals and the IMT-2000 forward communication signals of the IS-95A, IS-95B, or IS-95C filtered by the first and second filters 125 and 126 are sent to the first synthesizer 127. It is provided, and synthesized by the first synthesizer 127 (S12).

The forward synthesized signal generated from the first synthesizer 127 is provided to the first E / O converter 128 to be converted by the first E / O converter 128 into an optical signal, so that the It is transmitted to the optical repeater station 200 (S13).

The forward synthesized optical signal input to the optical relay station 200 through the optical cable is input to the second forward transmitter 220 as shown in FIG. 2. The forward synthesized optical signal input to the second forward transmitter 220 is input to the second O / E converter 221 and converted into an electrical signal (S14).

The forward synthesized signal generated from the second O / E converter 221 is input to the second divider 222, and the IS-95A, IS-95B, And the forward communication signals of the IS-95C and the forward communication of the IMT-2000, and are distributed to the third and fourth filters 223 and 224, respectively (S15).

The IMT-2000 forward communications input to the fourth filter 224 are filtered and provided to the fifth frequency converter 225, and are frequency converted by the fifth frequency converter 225 to be fifth and sixth transposed. Amplifiers / attenuators 227 and 228 are provided, respectively (S16).

Forward communication signals of the IS-95A, IS-95B, and IS-95C input to the third filter 223 are filtered and provided to the fourth preamplifier / attenuator 226, and the fourth preamplifier / Amplified / attenuated by an attenuator 226 and provided to the first amplifier 229. The forward communication signals of the IS-95A, IS-95B, and IS-95C provided to the first amplifier 229 are amplified by the first amplifier 229 and transmitted through the first band filter 232 and the antenna. do. Meanwhile, the IMT-2000 forward communications input to the fifth and sixth preamplifiers / attenuators 227 and 228 are amplified / attenuated and provided to the second and third amplifiers 230 and 231, and the second And amplified by the third amplifiers 230 and 231 and transmitted to the outside through the second and third band filters 233 and 234 and the antenna (S17).

Next, a relay process of the reverse communication signal will be described with reference to FIG. 4.

The reverse communication signals received through the antenna at the optical repeater station 200 are processed by the second reverse receiver 240 of the optical repeater station 200. Reverse communication signals from the antenna are input to the fourth to seventh band filters 241 to 244 of the second reverse receiver 240, respectively, and the fourth to seventh band filters 241 to 244 are frequencies. Detects the reverse communication signals of IMT-2000 and the reverse communication signals of IS-95A, IS-95B, or IS-95C from the reverse communication signal and provides them to the first to fourth low noise amplifiers 245 to 248. do. Then, the first to fourth low noise amplifiers 245 to 248 low noise amplify the reverse communication signals of the IMT-2000 and the reverse communication signals of the IS-95A, IS-95B, or IS-95C. To the frequency converters 249 to 251. Reverse communication signals of the IMT-2000 and reverse communication signals of the IS-95A, IS-95B, or IS-95C inputted to the sixth through eighth frequency converters 249 through 251 may be provided by the sixth through eighth frequencies. Frequency conversion is performed by the converters 249 to 251 (S21).

The reversed communication signals of the frequency-converted IMT-2000 and the reverse communication signals of IS-95A, IS-95B, or IS-95C are input to the second synthesizer 252 and synthesized by the second synthesizer 252. (S22).

The backward synthesized signal output from the second synthesizer 252 is input to the second E / O converter 253 and converted into an optical signal by the second E / O converter 253 to convert the optical signal through an optical cable. The repeater is transmitted to the mother station 100 (S23).

The reverse synthesized optical signal input from the optical repeater mark 200 through the optical cable is converted into an electrical signal by the first O / E converter 141 (S24).

Reverse communication signals generated from the first O / E converter 141 are provided to the first divider 142, are separated by the first divider 142 according to a frequency band, and the separated IMT-2000. Reverse communication signals and the reverse communication signals of the IS-95A, IS-95B, and IS-95C are distributed to the second to fourth frequency converters 143 to 145 and the first amplifier / attenuator 146, respectively ( S25).

Reverse communication signals of IS-95A, IS-95B, and IS-95C input to the second frequency converter 143 are frequency-converted and provided to the second amplifier / attenuator 147, wherein the third and fourth Reverse communication signals of the IMT-2000 input to the frequency converters 144 and 145 are frequency-converted by the third and fourth frequency converters 144 and 145, so that the third and fourth amplifiers / attenuators 148 and 149, respectively. Subsequently, the reverse communication signals of the IS-95A, IS-95B, and IS-95C input to the first and second amplifiers / attenuators 146 and 147 are amplified and attenuated so that the IS-95A, IS-95B, or The reverse communication signals of the IMT-2000 provided to the IS-95C base station 300 and input to the third and fourth amplifiers / attenuators 146 to 148 are amplified and attenuated and provided to the IMT-2000 base station 400. (S26).

Therefore, according to the above configuration, the IMT-2000 communication signal of the 2 GHz band can be utilized to use the optical module of the existing optical relay device, it is possible to reduce the cost during the IMT-2000 communication service.

As described above, according to the present invention, it is possible to realize a multi-frequency optical relay apparatus and method capable of relaying frequencies of 2 GHz or more through existing optical cables and optical modules.

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)

Means for converting a frequency of each of the one or more forward communication signals of the IMT-2000; Means for synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the forwarded communication signals of the frequency converted one or more IMT-2000; Means for converting the forward synthesized signal generated by the combining means into an optical signal and transmitting it through an optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing a forward synthesized signal from the converting means according to a frequency band; Means for frequency converting forward communications of one or more IMT-2000s distributed by the distribution means; And One or more of forward communications of one or more IMT-2000s frequency-converted by the frequency converting means and one or more of forward communications signals of the IS-95A, IS-95B, and IS-95C by the converting means, respectively. A forward signal optical repeater of multiple frequency bands, comprising means for transmitting. For converting a frequency of each of one or more reverse communication signals of IMT-2000 and at least one or more of the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; Way; Means for synthesizing the reverse signals converted by the frequency converting means; Means for converting the reverse synthesized signal synthesized by the combining means into an optical signal and transmitting the optical signal through an optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing the reverse forward composite signal converted by the conversion means according to a frequency band; And Frequency converting each of the reverse communications distributed by the distribution means, so that one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C. And a means for generating signals respectively. Consisting of an optical repeater home station and an optical repeater station linked by an optical cable, The optical repeater home country, Means for converting a frequency of each of the one or more forward communication signals of the IMT-2000; Means for synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the frequency converted one or more forward communication signals of IMT-2000; Means for converting the forward synthesized signal generated by the synthesizing means into an optical signal and transmitting it through the optical cable; Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing a reverse forward composite signal from the conversion means according to a frequency band; And Frequency converting each of the reverse communications distributed by the distribution means, so that one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C. Means for generating signals respectively, The optical repeater marks, Means for converting an optical signal input through the optical cable into an electrical signal; Means for distributing a forward synthesized signal from the converting means according to a frequency band; Means for frequency converting forward communications of one or more IMT-2000s distributed by the distribution means; One or more of forward communications of one or more IMT-2000s frequency-converted by the frequency converting means and one or more of forward communications signals of the IS-95A, IS-95B, and IS-95C by the converting means, respectively. Means for transmitting; For converting a frequency of each of one or more reverse communication signals of IMT-2000 and at least one or more of the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; Way; Means for synthesizing the reverse signals converted by the frequency converting means; And And a means for converting the backward synthesized signal synthesized by the combining means into an optical signal and transmitting the optical signal through an optical cable. a) converting a frequency of each of the one or more forward communication signals of the IMT-2000; b) synthesizing one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the frequency converted one or more forward communication signals of IMT-2000; c) converting the forward synthesized signal of step b) into an optical signal and transmitting it through an optical cable; d) converting an optical signal input through the optical cable into an electrical signal; e) distributing the forward synthesized signal according to step d) according to the frequency band; f) frequency converting one or more forward communications of the IMT-2000 according to step e); And g) transmit one or more signals of the frequency-converted one or more of the IMT-2000s converted in step f) and one or more of the IS-95A, IS-95B, and IS-95C forward communications signals in step d), respectively. The forward signal optical relay method of the multiple frequency band, characterized in that consisting of. a) converting a frequency of each of one or more of the reverse communication signals of one or more IMT-2000s and the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; b) synthesizing the reverse signals converted by step a); c) converting the backward synthesized signal synthesized in step b) into an optical signal and transmitting it through an optical cable; d) converting an optical signal input through the optical cable into an electrical signal; e) distributing the inverse forward composite signal converted by step d) according to the frequency band; And f) frequency converting each of the reverse communications distributed by step e) to perform one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C; or And generating more signals, respectively. a) converting a frequency of each of the one or more forward communication signals of the IMT-2000; b) synthesizing at least one or more of the forward communication signals of IS-95A, IS-95B, or IS-95C and the frequency converted one or more forward communication signals of IMT-2000; c) converting the forward synthesized signal generated by step b) into an optical signal to generate a forward optical signal, and transmitting the generated forward optical signal through the optical cable; d) converting a reverse optical signal input through the optical cable into an electrical signal; e) distributing the backward synthesized signal from step d) according to the frequency band; f) frequency converting each of the reverse communications distributed by step e) to perform one or more of the reverse communications of the one or more IMT-2000s and the reverse communications signals of the IS-95A, IS-95B, and IS-95C; or Generating each of the more signals; g) converting a forward optical signal input through the optical cable into an electrical signal; h) distributing the forward synthesized signal according to step g) according to the frequency band; i) frequency converting one or more forward communications of the IMT-2000 distributed by step h); j) transmitting one or more of the forward communications of the one or more IMT-2000s and the forward communications signals of the IS-95A, IS-95B, and IS-95C, respectively, frequency-converted by step i); k) converts a frequency of each of one or more reverse communication signals of one or more IMT-2000s and at least one or more of the reverse communication signals of IS-95A, IS-95B, or IS-95C received via an antenna; Doing; l) synthesizing the reverse signals converted by step k); And m) converting the backward synthesized signal synthesized in step l) into an optical signal and transmitting through the optical cable.