JP2000031879A - Wireless relay amplifier - Google Patents

Abstract

(57) [Summary] [PROBLEMS] To rationalize a wireless relay amplifying apparatus in a case where a plurality of operators assigned different transmission / reception frequency bands in mobile communication share one dead area. A base station arranged by a plurality of operators is provided.
All the radio waves from 5 are received and amplified, branched into the number of operating entities (42), and individually selected and amplified (43 to 4) for each operating entity.
4) After that, the signals are combined and amplified, and the mobile devices 56,
57. Similarly, the up-links from the mobile stations 56 and 57 are configured to be selectively amplified for each operator.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio relay amplifying apparatus which is installed in a dead zone common to a plurality of mobile communication systems having different operating entities assigned frequency bands adjacent to each other.

[0002]

2. Description of the Related Art A mobile communication system such as a mobile phone uses a radio line.
There may be a dead zone where radio waves cannot reach, such as an underground shopping mall or an underground parking lot. In recent years, with the spread of mobile devices, there has been an increasing demand for services in these blind areas, and wireless relay amplifiers have been installed as means for relieving these blind areas.

[0003] Further, with the growing demand for portable telephones and the like, a plurality of different operators have been established, and transmission and reception frequencies have been assigned to each of them.

FIG. 5 is an explanatory diagram of frequency band allocation, for example, an example of a frequency band allocation situation for a plurality of mobile communication systems such as a mobile phone system.
As shown in this figure, multiple systems with different operating entities,
.. N, the downlink bands for transmitting radio waves from the base station to the mobile station of each system are arranged adjacently, and the uplink lines for transmitting radio waves from the mobile station to the base station are similarly arranged adjacently. May be.

[0005] FIG. 6 is a diagram showing an example of the arrangement of blind areas of a plurality of operating systems,..., N to which the frequency bands of FIG. In the example of FIG. 6, when the mobile station is in the dead area indicated by the solid line, for example, the mobile station 7 of the system can perform wireless communication because the base station 2 of the system is in the dead area. In the system, for example, the mobile unit 6 of the system cannot perform wireless communication because the base station 1 of the system is outside the blind area.

Conventionally, as a means for relieving a dead area as shown in FIG. 6, a wireless relay amplifier as shown in FIG. 7 is installed for each system in one dead area to relieve the dead area. Was. FIG. 7 is a block diagram of a conventional wireless relay amplification device, and a plurality of systems to n are the same device. In the figure, 14 and 15 are transmission / reception antennas, 8 and 12 are down-band filters, 9 and 13 are up-band filters, and 10 and 11 are amplifiers. System n
Has the same configuration. In the dead zone as shown in FIG. 6, the relay amplifying devices (n-1) of the system to the system n except for the system relay amplifying device of FIG. 7 are installed in one dead zone.

As described above, if there are a plurality of operation systems that provide services to the same blind area, a relay amplifier for each system is required, and the space for accommodating the equipment installed in the same blind area is increased, and the cost is increased. The height is also noticeable and unrealistic.

Therefore, as a countermeasure against the above-mentioned problem, a configuration is employed in which a filter for removing a band of a system that does not need to be relay-amplified is connected to a relay amplification device that commonly amplifies radio waves of all systems having the same dead zone as a service area. There is.

FIG. 8 is a diagram showing an example of the configuration of a wireless relay amplifying apparatus to which a band elimination filter of an unnecessary system is connected. In the figure, reference numerals 24 and 33 denote transmission / reception antennas, and reference numerals 25 and 32 denote band elimination filters for eliminating the band of unnecessary systems.
Reference numeral 5 denotes a system downlink band elimination filter, and reference numeral 32 denotes a system uplink band elimination filter. 26,3
Reference numeral 0 denotes a bandpass filter that passes through all bands of the downlinks of all the systems to n, 27 and 31 denote bandpass filters that pass all bands of the uplinks of all the systems to n, and 28 and 29 denote amplifiers.

FIG. 9 shows the band elimination filter 2 of the apparatus shown in FIG.
It is an attenuation characteristic example figure of 5, 32. This band elimination filter removes the frequency band of the system that does not require relay amplification,
It has the characteristic of passing all bands of the other systems to n.

[0011]

However, in the above-mentioned conventional apparatus, when the bands of radio waves assigned to a plurality of operators are adjacent to each other, the channel used by the adjacent system is set to the attenuation band of the band elimination filter. When it is near the boundary, in the example of FIG. 9, the signal of the channel near the upper limit of the adjacent system is attenuated by x ₁ dB. In order to make the attenuation of the channel near the boundary sufficiently small, it is required that the attenuation gradient of the filter has a steep characteristic. In order to realize such a band elimination filter, it is necessary to use an element having a very high Q or to use a complicated configuration having an increased order. There is a problem of difficulty.

SUMMARY OF THE INVENTION An object of the present invention is to avoid the above-mentioned problems of the conventional devices and filters from being enlarged, expensive, and difficult to adjust, and a plurality of wireless systems serve as one blind area. Sometimes it is possible to rescue the entire system with only one wireless relay amplifying device.
An object of the present invention is to provide a wireless relay amplifying device which realizes economical operation.

[0013]

SUMMARY OF THE INVENTION A radio relay amplifying apparatus according to the present invention is provided in a common blind zone in a zone of a base station in which a plurality of operating entities performing mobile communication services to which different transmission / reception frequency bands are allocated are arranged. An installed relay amplifying device, comprising: an antenna for a base station for transmitting and receiving radio waves from a base station arranged by the plurality of operating entities; and an uplink frequency connected to the antenna and assigned to the plurality of operating entities. A base station duplexer for demultiplexing the entire band and the entire downlink frequency, a downlink low noise amplifier for amplifying a downlink signal from the base station duplexer, and an output of the downlink low noise amplifier. A downlink distributor that branches into the number of operators that share the dead area; and selectively amplifies downlink frequency band signals that are connected to the downlink distributor and assigned to each operator. A plurality of downlink dedicated selection amplifying unit, and the downlink combiner for combining the outputs of the downlink dedicated selection amplification portion of the plurality of the downlink power amplifier for amplifying the output of said downlink synthesizer,
A mobile station antenna for transmitting and receiving radio waves from a mobile station receiving the services of the plurality of operators, and supplying an output of the downlink power amplifier to the mobile station antenna and an uplink frequency from the mobile station antenna; A duplexer for mobile stations for demultiplexing and outputting received radio waves in all bands, an uplink low-noise amplifier for amplifying an uplink signal from the duplexer for mobile stations, and an output of the uplink low-noise amplifier, An upstream distributor that branches into the number of operators that share the same, a plurality of uplink individual selection amplifiers that are connected to the uplink distributor and selectively amplify the uplink frequency band signals assigned to each operator, respectively. An uplink combiner that combines the outputs of the plurality of uplink individual selection amplifiers, and an uplink power amplifier that amplifies the output of the uplink combiner and inputs the amplified output to the base station duplexer. Than it is.

Further, each of the plurality of downlink individual selection amplifiers and the plurality of uplink individual selection amplifiers corresponds to a reception level from a base station arranged by the plurality of operators or a transmission level to the base station. Level adjusting means for adjusting the level, first frequency converting means for converting to an intermediate frequency lower than the transmission / reception frequency, and frequency selecting means for selecting a frequency band of the operating subject from among the converted intermediate frequency signals, Second frequency conversion means for converting the selected frequency band signal of the operation subject to the original transmission / reception frequency, and power-amplifying the transmission / reception frequency band signal of the operation subject output from the second frequency conversion means And amplifying means for outputting the output.

[0015] Further, the uplink individual selection amplification unit detects the use frequency of each of a plurality of operating entities using the device based on a communication signal extracted by a directional coupler provided at a stage subsequent to the frequency selection means. A usage frequency detecting unit is provided.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIGS. 1 to 3 are structural examples showing an embodiment of the present invention. FIG. 1 is a block diagram of a wireless relay amplifier of the present invention, and FIGS. 2 and 3 are partial block diagrams of the present invention. In FIG. 1, reference numeral 34 denotes a base station (BS) of an operating entity (hereinafter, referred to as a system); 35, a base station of system n (plurality); 56, a mobile station (MS) of the system; is there. 36,5
5 is a transmitting / receiving antenna, 37 and 47 are duplexers, 38 and 48
Are the downlink all bandpass filters of the system to n, 3
Reference numerals 9 and 49 denote upstream all bandpass filters of the system to n, 40, 41, 46, and 54 denote amplifiers, and 42 and 53 denote n.
Dividers, 45 and 50 denote n combiners, 43 and 44 denote downstream individual selection amplifying units of each system, and 51 and 52 denote upstream individual selection amplifying units of each system.

The operation of the present invention will be described below with reference to FIG. First, the downlink will be described. Radio waves from the base stations 34 and 35 of the plurality of operation systems to n are received by the base station transmission / reception antenna 36, and all the band signals of to n are selected by the downlink input filter 38 of the duplexer 37. After being amplified by the noise common amplifier 41, the signal is distributed by the n distributor 42 to the downstream individual selection amplifiers 43 to 44 of each operating entity. The individual selection amplifying units 43 to 44 are provided corresponding to the operation system requiring the relay amplification. The outputs of the individual selection amplifiers 43 to 44 are combined by an n combiner 45, amplified by a downlink common power amplifier 46 that amplifies the downlink signal to a specified level, and then passed through an output filter 48 for all downlink systems. , From the transmitting / receiving antenna 55 for mobile stations to the mobile stations 56 to 57 of the respective systems.

Next, the uplink will be described. Radio waves from the mobile stations 56 to 57 of the operation system to n are received by the transmission / reception antenna 55 for mobile station, and all the band signals of the system to n are selected by the uplink input filter 49 of the duplexer 47, and the uplink low noise After the signal is amplified by the common amplifier 54, the signal is distributed by the distributor 53 to the upstream individual selection amplifiers 51 to 52 of the respective operating entities. The outputs of the uplink individual selection amplifiers 51 to 52 provided corresponding to the operation system requiring the relay amplification are combined by the n combiner 50, and the uplink common power amplifier 40 amplifies the uplink signal to a specified level. After amplification, the signal passes through the output filter 39 for all systems in the uplink and is transmitted from the transmitting / receiving antenna for base stations to the base stations 34 to 3 of the respective systems.
Send to 5.

FIG. 2 shows the downlink individual selection amplifier 4 of FIG.
It is a structural example figure about each of 3-44. In the figure, 58 is a variable attenuator, 59 and 65 are all system band filters, 60 and 66 are amplifiers, 61 and 64 are frequency converters, 62 and 63 are IF filters, and 67 is a local oscillator. 1 is attenuated to a specified level by a variable attenuator (ATT) 58 in FIG. 2 and passes through the entire downlink frequency band of all systems to n. is selected by the filter 59, is amplified to a required level by the low noise amplifier 60, after being converted to an IF frequency (f ₁₁ -f _L0) by the signal f _L0 input from a local oscillator 67 by the frequency converter 61, The IF filters 62 to 63 select only the frequency band components of the operation main body, and block the passage of the frequency band components of the other operation main bodies to n. In order to reduce the cost of the IF filter, for example, two filters having a half number of stages of the necessary order (62
And 63) are cascaded, and a buffer amplifier (not shown) is inserted between them to stabilize the filter characteristics.

The signals of the system selected by the IF filters 62 to 63 are converted by the frequency converter 64 into the local oscillator 6.
The signal f _L0 is inversely converted to the original frequency band f ₁₁ by the signal f _L0 , and the unnecessary wave generated by the frequency converter 64 is attenuated by the filter 65 and amplified by the power amplifier 66. Input to the container 45. The downlink individual selection amplification units to n of other systems have the same configuration. Here, the characteristics of the IF filters 62 to 63 are determined by the required attenuation for the detuning frequency and the pass band for each operating entity.

FIG. 4 is a diagram showing an example of transmission characteristics of the IF filters 62 to 63 used in the individual selection amplifiers 43 to 44 in FIG. The attenuation outside the pass band of this IF filter has a steep characteristic. The deviation in the pass band of this filter is small, and the loss X ₂ of the band to be passed can be reduced as compared with the band elimination filter used in the conventional configuration of FIG. Further, since the pass band is converted from a high frequency to an IF frequency, it is easy to realize an IF filter having such a characteristic that the attenuation gradient is steep.

The amplifiers 60, 66, 68, and 75 in FIG. 2 and FIG. 3 to be described later have a buffering function in addition to amplifying to a required level. It has a function of preventing unnecessary flows of unnecessary waves and backflow of unnecessary waves generated in the individual selection amplification unit of the own system. Each of the uplink individual selection amplifiers 51 to 52 has the same configuration.

FIG. 3 shows another configuration example of the uplink individual selection amplifiers 51 to 52 of the embodiment shown in FIG. In the figure, 77 is a variable attenuator, 76 and 69 are all system bandpass filters, 75 is a low noise amplifier, 74 and 70 are frequency converters, 71 and 73 are IF filters, and 72 is a direction for extracting a monitor signal. Sex coupler, 67 is a local oscillator, 78
Denotes a usage frequency detection unit. The configuration of the individual selection amplifying sections 51 to 52 in FIG. 1 for this uplink is the same as that of the downlink individual selection amplifying sections 43 to 44 in FIG. 2, but after the operation system individual selection filter 73 in the IF stage in FIG. , Directional coupler 7
2 is provided with a usage frequency detection unit 78 for monitoring the presence or absence of a call signal, the frequency of use of each operating entity using the apparatus is measured, the usage ratio of each operating entity is clarified, and the cost is reduced. Configuration.

[0024]

As described above in detail, by implementing the present invention, when there is a common dead zone in a plurality of operating subject zones, a relay amplifying device dedicated to each operating subject can be provided. The entire system can rescue the blind area only by installing one wireless relay amplifier having a pair of uplink and downlink relay amplification functions without installing the same number of operators. Moreover, it is possible to set the gain according to the arrival wave level from the base station of each operator,
In addition, it is possible to provide an economical and compact wireless relay amplifier capable of sharing the cost by monitoring the frequency of use, and the practical effect is extremely large.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a block diagram showing an embodiment of a downlink and uplink individual selection amplifier of the present invention.

FIG. 3 is a block diagram showing another embodiment of the uplink individual selection amplifier of the present invention.

FIG. 4 is a characteristic example diagram of an IF filter used in the present invention.

FIG. 5 is an explanatory diagram of frequency band allocation in a mobile communication system.

FIG. 6 is a diagram illustrating an example of a dead area in a zone of a system to n.

FIG. 7 is a configuration example diagram of a conventional wireless relay amplifying device.

FIG. 8 is a configuration example diagram of a conventional wireless relay amplifying device.

FIG. 9 is a characteristic example diagram of a band elimination filter used in a conventional device.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 system base station 2 system base station 3 system n base station 4, 6 system mobile station 5 system n mobile station 7 system mobile station 8 system downlink input filter 9 system uplink output filter 10 system downlink amplifier 11 system uplink Line amplifier 12 System downlink output filter 13 System uplink input filter 14 System base station transmission / reception antenna 15 System mobile station transmission / reception antenna 16 System n base station transmission / reception antenna 17 System n downlink input filter 18 System n Upstream output filter 19 Downlink amplifier for system n 20 Uplink amplifier for system n 21 Downstream output filter for system n 22 Upstream input filter for system n 23 Antenna for mobile station for system n 24 Transmitting and receiving antenna for base station 25 , 32 band rejection filter 26 downlink input filter 27 uplink output filter 28 downlink amplifier 29 uplink amplifier 30 downlink output filter 31 uplink input filter 33 transmitting / receiving antenna for mobile station 34 system base station 35 system n base station 36 base Transmission / reception antenna for office 37 Shared device for base station 38 Downlink input filter 39 Uplink output filter 40 Common amplifier for uplink output 41 Common amplifier for downlink input 42,53 n distributor 43 Downlink individual selection amplifying unit 44 for system Downlink individual selection amplifying section for system n 45, 50 n combiner 46 Downlink output common amplifier 47 Mobile station duplexer 48 Downlink output filter 49 Uplink input filter 51 Uplink individual selection amplifying section for system 52 System n For uplink Selective amplification unit 54 Common amplifier for uplink input 55 Transmission / reception antenna for mobile station 56 System mobile station 57 System n mobile station 58 RF variable attenuator 59, 65 Down-band whole filter 60, 66 Amplifier 61, 64 Frequency converter 62, 63 System unit IF filter 67 Local oscillator 68,75 Uplink common amplifier 69,76 Upband whole filter 70,74 Frequency converter 71,73 System unit IF filter 72 Directional coupler 77 RF variable attenuator 78 Usage frequency detection Department

Claims (3)

[Claims] 1. A relay amplifying device installed in a common blind zone in a zone of a base station in which a plurality of operators performing mobile communication services are allocated with different transmission / reception frequency bands, and An antenna for a base station for transmitting and receiving radio waves from a base station arranged by an operator, and demultiplexing the entire uplink frequency band and the entire downlink frequency band assigned to the plurality of operators connected to the antenna. A duplexer for a base station; a downlink low-noise amplifier for amplifying a downlink signal from the duplexer for the base station; and the output of the downlink low-noise amplifier is branched into the number of operating entities sharing the dead zone. A downlink distributor; a plurality of downlink individual selection amplifying units connected to the downlink distributor and selectively amplifying downlink frequency band signals assigned to the respective operating entities, respectively; A down combiner for combining the outputs of the individual selection amplifiers, a down power amplifier for amplifying the output of the down combiner, and a mobile station antenna for transmitting and receiving radio waves from mobile stations receiving the services of the plurality of operators. A mobile station duplexer that supplies the output of the downlink power amplifier to the mobile station antenna and that separates and outputs the received radio waves of the entire uplink frequency from the mobile station antenna; An uplink low-noise amplifier that amplifies an uplink signal from a duplexer; an uplink distributor that branches the output of the uplink low-noise amplifier into the number of operating entities sharing the dead area; and connecting to the uplink distributor. A plurality of uplink individual selection amplifiers for selectively amplifying the uplink frequency band signals assigned to each operator, an uplink synthesizer for combining the outputs of the plurality of uplink individual selection amplifiers, A relay amplifier comprising: an upstream power amplifier that amplifies an output of the upstream combiner and inputs the amplified output to the base station duplexer. 2. The plurality of downlink individual selection amplifiers and the plurality of uplink individual selection amplifiers each correspond to a reception level from a base station arranged by the plurality of operators or a transmission level to the base station. Level adjusting means for adjusting the level, first frequency converting means for converting to an intermediate frequency lower than the transmission / reception frequency, and frequency selecting means for selecting a frequency band of the operating subject from among the converted intermediate frequency signals, Second frequency conversion means for converting the selected frequency band signal of the operation subject to the original transmission / reception frequency, and power-amplifying the transmission / reception frequency band signal of the operation subject output from the second frequency conversion means 2. The relay amplifying device according to claim 1, further comprising an amplifying means for outputting the signal. 3. The uplink individual selection amplification unit according to claim 2, wherein each of a plurality of operation entities that use the device by a communication signal extracted by a directional coupler provided at a subsequent stage of the frequency selection unit. 3. The relay amplifying device according to claim 1, further comprising a use frequency detection unit for detecting a frequency.