KR100383722B1 - Transmiting and receiving apparatus of mobile communicating system having coaxial cables - Google Patents

Abstract

A transceiver for a mobile communication system having a coaxial cable capable of reducing the capacity of a power amplifier and reducing the noise figure of a low noise amplifier to minimize data loss due to the coaxial cable is disclosed. The present invention is connected between the synthesizer and the power amplifier of the transmitter and between the low noise amplifier and the distributor of the receiver, respectively, so that the power amplifier and the transmitting antenna are closer, so that the capacity of the power amplifier can be reduced, the low noise amplifier Since the distance between the antenna and the receiving antenna is closer, it is possible to reduce the noise figure of the low-noise amplifier, and when the optical cable is used instead of the coaxial cable, the cost of embedding the coaxial cable can be reduced.

Description

Transmitter and receiver of mobile communication system having coaxial cable {TRANSMITING AND RECEIVING APPARATUS OF MOBILE COMMUNICATING SYSTEM HAVING COAXIAL CABLES}

The present invention relates to a base station of a mobile communication system, and more particularly, to a base station of a mobile communication system capable of reducing the capacity of a power amplifier and reducing the noise figure of a low noise amplifier.

In general, a mobile terminal service provided to a base station in a code division multiple access communication system includes radio control for transmitting and receiving communication signals remotely and optical control for transmitting and receiving communication signals using an optical repeater.

However, since the optical repeater is directly connected to the base station, the coverage and call quality of the base station are deteriorated according to the number of connection of the optical repeater, and the coverage of the base station is reduced.

Therefore, the base station of the mobile communication system through the radio control is as shown in FIG. Referring to FIG. 1, the base station includes a communication channel processor 10, a transceiver 30, and an antenna 50 for transmission and reception.

Here, the communication channel processor 10 generates a forward communication signal, and processes the reverse communication signal received from the transceiver 30, which will be described later.

The communication channel processing unit 10 processes each of the forward and reverse communication signals input through the transmission and reception channels allocated for the mobile terminal service.

Here, the forward communication signal to be transmitted through the basic frequency channel means a digital signal of a known band having a call and overhead information, and the overhead information includes pilot channel information, paging channel information, and synchronization channel information. do.

The transceiver 30 is composed of a plurality of transmitters 31-3n and a plurality of receivers 41-4n, and the plurality of transmitters 31-3n are forward communication output from the communication channel processor 10. The transmitter 31 is provided to frequency convert, synthesize, and amplify the signal, and each transmitter 31 is provided with a combiner 31a, a power amplifier 31b, and a band pass filter 31c.

That is, the combiner 31a synthesizes the forward communication signal output from the communication channel processor 10, and the synthesized signal of the synthesized combiner 31a is supplied to the power amplifier 31b, and this power amplifier ( 31b) amplifies this synthesized signal.

The band filter 31c receiving the amplified synthesized signal filters the amplified synthesized signal, and provides the filtered analog communication forward communication signal to the transmitting antenna 51a through the coaxial cable 31d. The transmitting antenna 51 transmits this forward communication signal.

On the other hand, the plurality of receivers (41-4n) is provided to distribute the analog communication signal of the analog form supplied from the receiving antenna (53a) via the coaxial cable (41a) and to be supplied to the communication channel processing unit 10 of the corresponding channel. Each of these receivers 41 is provided with a band pass filter 41b, a low noise amplifier 41c, and a divider 41d.

The band filter 41b filters the reverse communication signal supplied from the receiving antenna 53a through the coaxial cable 41a, and the low noise amplifier 41c receiving the filtered reverse communication signal transmits the filtered reverse communication. Amplify the signal and provide the amplified reverse communication signals to the divider 41d.

The distributor 41d receiving the amplified reverse communication signal is separated according to the type of the reverse communication signal, and the separated reverse communication signal is provided to the communication channel processing unit 10.

In the base station of the general mobile communication system as described above, a coaxial cable is connected between the transceiver 30 and the transmitting antenna and the receiving antenna, but in this case, the capacity of the power amplifier increases as the frequency increases, and the low noise amplifier An increase in the noise figure increases the loss of communication signals transmitted from the coaxial cable. Therefore, in order to eliminate the loss of the communication signals described above, an expensive coaxial cable of more than 7/8 inches is used, which has a low loss between the power amplifier and the antenna. Often occurred.

SUMMARY OF THE INVENTION The present invention has been made to solve the above inconvenience, and an object of the present invention is to connect power between a synthesizer and a power amplifier in a transmitter in a base station and between a low noise amplifier and a divider in a receiver using a coaxial cable, thereby simplifying power. It is an object of the present invention to provide a transceiver of a mobile communication system having a coaxial cable capable of reducing the capacity of an amplifier and reducing the loss of a communication signal by reducing the noise figure of a low noise amplifier.

Transmission and reception apparatus of a mobile communication system having a coaxial cable according to the present invention for achieving the above object,

A synthesizer for synthesizing forward communication signals supplied from a communication channel processor, a coaxial cable for transmitting a synthesized signal of the synthesizer, a power amplifier for amplifying a synthesized signal transmitted through the coaxial cable, and an amplified synthesized signal of the power amplifier A plurality of transmitters including a band filter for filtering and transmitting through the antenna for transmission; And

A band pass filter for filtering reverse communication signals received through a receiving antenna, a low noise amplifier for amplifying a reverse communication signal of the band pass filter, a coaxial cable for transmitting the amplified reverse communication signal, and a reverse communication transmitted from the coaxial cable Characterized in that it consists of a plurality of receivers provided as a distribution unit for distributing the signal according to the type of signal to the communication channel processing unit.

According to the present invention, the capacity of the power amplifier can be reduced since the transmission antenna and the power amplifier are installed in close proximity, and the low noise amplifier and the antenna, which amplify the reverse communication signal, are installed close to eliminate the loss of the communication signals by the coaxial cable. It can improve the noise figure to reduce the cost, and also reduce the construction cost due to expensive coaxial cable laying.

1 is a diagram illustrating a configuration of a base station of a general mobile communication system.

2 is a block diagram of a transceiver of a mobile communication system according to an exemplary embodiment of the present invention.

3 illustrates a configuration of a base station of a mobile communication system according to another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: communication channel processing unit 301-30n: transmission unit

311-3n1: Synthesis section 313-3n3, 415-4n5: Coaxial cable

315-3n5: Power amplifier 317-3n7, 411-4n1: Band filter

401-40n: Receiver 413-4n3: Low noise amplifier

417-4n7: Splitter 511-51n: Transmission antenna

531-53n: receiving antenna 300: transceiver

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram showing the configuration of a transceiver of a mobile communication system according to the present invention. In FIG. 2, a transceiver of a mobile communication system according to the present invention is provided with a communication channel processor 100, a transceiver 300, and antennas 511-51n and 531-53n.

The transceiver 300 is composed of a plurality of transmitters 301-30n and a plurality of receivers 401-40n, and the plurality of transmitters 301-30n are forward communications output from the communication channel processor 100. The transmitter 301 is provided to synthesize and amplify a signal, and each transmitter 301 is provided with a combiner 311, a coaxial cable 313, a power amplifier 315, a band pass filter 317, and an antenna 511.

Here, the combiner 311 is installed inside the base station, and the power amplifier 315 and the band pass filter 317 are connected to the antenna 511. Then, a coaxial cable is connected between the combining section 311 of the base station and the power amplifier 315 connected to the antenna 511.

That is, the combiner 311 synthesizes a forward communication signal output from the communication channel processor 100, and the synthesized signal of the synthesized synthesizer 311 is a forward communication signal processor 315 through a coaxial cable 313. Is provided.

The forward communication signal transmitted through the coaxial cable is supplied to a power amplifier 315, which amplifies this synthesized signal.

The band filter 317 receiving the amplified synthesized signal filters the amplified synthesized signal and provides the filtered analog communication forward communication signal to the transmitting antenna 511 through a coaxial cable. The credit antenna 511 transmits this forward communication signal.

On the other hand, the plurality of receivers (401-40n) is provided to distribute the analog communication signal of the analog form supplied from the receiving antenna (531-53n) and to be supplied to the communication channel processing unit 100 of the corresponding channel, respectively The receiver 401 is provided with a band pass filter 411, a low noise amplifier 413, a coaxial cable 415, and a distribution unit 417. Here, the band filter 411 and the low noise amplifier 413 are connected to the receiving antenna 531, and the distribution unit 311 is provided inside the base station. The distribution unit 311 inside the base station and the low noise amplifier 413 connected to the antenna 513 are connected by a coaxial cable.

The band filter 411 filters the reverse communication signal supplied from the receiving antenna 531, and the low noise amplifier 413 receiving the filtered reverse communication signal amplifies the filtered reverse communication signal and amplifies the filtered reverse communication signal. Reverse communication signals are provided to the distributor 417 via a coaxial cable 415.

The splitter 417 receiving the amplified reverse communication signal is separated according to the type of the reverse communication signal, and the separated reverse communication signal is provided to the communication channel processing unit 100.

Therefore, coaxial cables 313 and 415, respectively, between the synthesizer 311 and the power amplifier 315 of the transmitter 301 and between the low noise amplifier 413 and the distributor 417 of the receiver 401, respectively. Since the connection between the power amplifier 315 and the transmitting antenna 511 is closer, the capacity of the power amplifier 315 can be reduced, and the low noise amplifier 413 and the receiving antenna 531 are closer to each other. The noise figure of 413 can be reduced.

3 is a block diagram illustrating a transmission and reception apparatus of a mobile communication system according to another embodiment of the present invention. In FIG. 3, the same reference numerals are attached to the same parts as FIG. 2, and detailed description thereof will be omitted.

In FIG. 3, a transceiver of a mobile communication system according to the present invention is provided with a communication channel processor 100, a transceiver 300, and antennas 511-51n and 531-53n for transmission and reception.

The transceiver 300 is composed of a plurality of transmitters 301-30n and a plurality of receivers 401-40n, and the plurality of transmitters 301-30n are forward communications output from the communication channel processor 100. The transmitter 301 is configured to synthesize and amplify a signal, and each transmitter 301 includes a combiner 311, an optical modulator 611, an optical cable 613, an optical demodulator 615, a power amplifier 315, and a band pass filter ( 317).

Here, the combiner 311 and the optical modulator 611 are installed inside the base station, and the optical demodulator 615, the power amplifier 315, and the band pass filter 317 are connected to the antenna 511. The optical modulator 311 and the optical demodulator 615 are connected by an optical cable 613.

That is, the synthesis unit 311 synthesizes the forward communication signal output from the communication channel processing unit 100, and the synthesized signal of the synthesized synthesis unit 311 is provided to the optical modulator 611, and the synthesized signal The received optical modulator 611 modulates this synthesized signal into an optical signal and then provides it to the optical demodulator 615 through an optical cable.

The optical demodulator 615 demodulates the optically modulated composite signal, and supplies the demodulated forward communication signal to the power amplifier 315, which amplifies the synthesized signal.

The band filter 317 receiving the amplified synthesized signal filters the amplified synthesized signal, and provides the filtered analog communication forward communication signal to the transmitting antenna 511, and the transmitting antenna 511. Transmits this forward communication signal.

On the other hand, the plurality of receivers (401-40n) is provided to distribute the analog communication signal of the analog form supplied from the receiving antenna (531-53n) and to be supplied to the communication channel processing unit 100 of the corresponding channel, respectively The receiver 401 is provided with a band filter 411, a low noise amplifier 413, an optical modulator 711, an optical cable 713, an optical demodulator 715, and a distribution unit 417.

Here, the distribution unit 417 and the optical demodulator 715 are installed inside the base station, and the optical modulator 711, the low noise amplifier 413, and the band pass filter 411 are sequentially connected to the antenna 511. The optical modulator 711 and the optical demodulator 715 are connected by an optical cable 713.

The band filter 411 filters the reverse communication signal supplied from the receiving antenna 531, and the low noise amplifier 413 receiving the filtered reverse communication signal amplifies the filtered reverse communication signal and then modulates the optical modulator. The optical modulator 711 receiving the reverse communication signal modulates the reverse communication signal into an optical signal and provides the optical demodulator 715 through the optical cable 713.

The optical demodulator 715 demodulates this optically modulated reverse communication signal and provides this demodulated reverse communication signal to the distributor 417. The distributor 417, having received the amplified reverse communication signal, is separated according to the type of the reverse communication signal, and the separated reverse communication signal is provided to the communication channel processor 10. FIG.

Therefore, the cable is embedded between the combining section 311 and the power amplifier 315 of the transmitter 301 and between the low noise amplifier 413 and the distributor 417 of the receiver 401, respectively. The cost can be greatly reduced.

As described above, the transmission and reception apparatus of the mobile communication system having the coaxial cable according to the present invention is connected between the synthesizer and the power amplifier of the transmitter and between the low noise amplifier and the distributor of the receiver, respectively. The capacity of the power amplifier can be reduced because the amplifier is close to the transmitting antenna, and the noise figure of the low noise amplifier is reduced because the amplifier is close between the low noise amplifier and the receiving antenna, and when the optical cable is used instead of the coaxial cable, It can reduce the cost of laying.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (4)

Synthesizing forward communication signals supplied from the communication channel processing unit and amplifying unit for amplifying a synthesizer installed inside the base station, a transmission coaxial cable for transmitting the synthesis signal of the synthesis unit, and a synthesized signal transmitted through the transmission coaxial cable A plurality of transmitters including a power amplifier and a band pass filter for filtering the amplified synthesized signal of the power amplifier through a transmission antenna, and connected to the transmission antenna in order of a power amplifier and a band filter; And A band pass filter sequentially connected to the receiving antenna and filtering reverse communication signals received through the receiving antenna, a low noise amplifier amplifying the reverse communication signal of the band pass filter, a receiving coaxial cable transmitting the amplified reverse communication signal, And a plurality of receivers installed in the base station and configured to distribute a reverse communication signal transmitted from the reception coaxial cable according to a signal type and to provide the communication channel processing unit to the communication channel processing unit. The transceiver of the mobile communication system. The method of claim 1, wherein the transmission coaxial cable An optical modulator installed inside the base station and modulating the synthesized signal of the combining unit into an optical signal; An optical cable for transmitting an optical signal of the optical modulator; And And an optical demodulator, connected to the low noise amplifier, for demodulating and outputting an optical signal transmitted through an optical cable as a forward communication signal. The method of claim 1, wherein the transmission and reception coaxial cable A base station of a mobile communication system, characterized by being less than 1.27 cm. The method of claim 1, wherein the receiving coaxial cable An optical modulator for modulating a reverse communication signal of the low noise amplifier into an optical signal; An optical cable for transmitting an optical signal of the optical modulator; And Transceiver of the mobile communication system having a coaxial cable, characterized in that for demodulating the optical signal transmitted through the optical cable to output a reverse communication signal.