JP3466386B2 - Relay amplification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently cancel a blind part owing to the radio obstacle of a blind sector by arranging two repeating devices constituted by a diversity system in the small blind sector in the bi-directional repeating amplification system of mutual communication radio waves between a radio base station and the mobile station of the small blind sector in a service area. SOLUTION: When the repeater amplifier device 2-1 is installed in the whole service area 9-2, the repeater amplifier device 2-2 is installed in a position where a part of areas are overlapped for a blind area 9-4 generated by the radio obstacle 10 of the service area 9-2, and a service area 9-3-2 eliminates the blind sector 9-4 by the repeater device 2-1. Thus, two antennas for the base station and for the mobile station are required, a diversity effect is obtained and the power of output in the respective repeating devices becomes small. The repeater devices are facilitated and the blind sector can be canceled by miniaturization by power saving of the repeater.

Description

Description: BACKGROUND OF THE INVENTION [0001] 1. Field of the Invention [0002] The present invention relates to a radio relay amplification system for a blind spot in an automobile telephone system, and more particularly to a relay amplification system in a blind area having a small area. 2. Description of the Related Art At present, since a car telephone system uses a radio line, there are blind zones where radio waves cannot reach, such as buildings, underground shopping malls, and underground parking lots. Recently, with the spread of mobile devices, there is an increasing demand for services in these blind areas. Therefore, wireless relay amplifiers are being installed to rescue these blind areas, but especially in small-scale relay amplifiers that serve small areas, the distance between the antenna and the mobile device is short, so that small output power is required. , Low power, and small size, but have different problems from large-scale repeater amplifiers that serve a wide area. FIG. 1 is a configuration diagram of a conventional relay amplification system. In the figure, 1 is a base station, 11 is a base station transmitting / receiving antenna, 2 is a relay amplifier, 21 is a base station antenna,
22 is a mobile station antenna, 8-1 to 8-n are mobile terminals, 8
1-1 to 81-n are antennas of the mobile device, 9-2 is an area requiring service, and 9-3 is an obstacle 1 such as an indoor pillar.
0-4 is an area of good quality due to the presence of 0, 9-4 is an area of poor quality due to the presence of an obstacle 10 such as a pillar in the room, and 9-1 is an AGC (automatic gain control) of the upstream amplification unit of the relay amplifier 2. ) Is the service area when working. A downlink radio wave transmitted from the base station transmitting / receiving antenna 11 of the base station 1 is received by the base station antenna 21 of the relay amplifying device 2, amplified, and radiated from the mobile station antenna 22. . The service area in the receivable range of the downlink radio wave is 9-2, which is a combination of the high quality area 9-3 and the poor quality area 9-4. FIG. 2 is a block diagram showing a configuration of a conventional relay amplifier 2. In the figure, 31 is a duplexer for base stations, 32 is a duplexer for mobile stations, and 40 is an AT for downlink AGC.
T and 50 are ATTs for upstream AGC, 41 is a downstream relay amplifier, 51 is an upstream relay amplifier, 42 is a downlink directional coupler, 52 is an uplink directional coupler, and 43 is a downlink detection rectifier. , 53 are an upstream detection and rectifier, 44 is a downstream AGC controller, and 54 is an upstream AGC controller. Since the principle is the same for the upstream system and the downstream system, the downstream system will be described. For example, in a building pillars and walls,
There are many miscellaneous radio obstacles such as lockers, and the line quality level required for the entire area cannot be obtained, which may result in more blind spots or places with poor communication quality in that area. is there. 9 is the place. In this case, the communication quality of the mobile device 8-2 deteriorates. There are also the following problems. Relay device 2
This is a problem from the hardware side, and will be described with reference to FIG.
The radio wave from the base station 1 input from the base station antenna 21 passes through the base station duplexer 31, passes through the ATT 40, is amplified by the amplifying unit 41, is partially monitored by the directional coupler 42, and is partially monitored by the mobile station. After passing through the duplexer 32, the mobile station antenna 22
Sent from. The monitor output proportional to the signal level is detected by the rectifier 43 and input to the AGC controller 44.
When the transmission output level becomes higher than a predetermined level, AG
The C control unit 44 operates to suppress the transmission output level by increasing the attenuation of the ATT 40 (to make it constant). The AGC function has a function of immediately lowering the gain when the input level of the amplification section 41 becomes high to protect the semiconductor of the amplification section 41, and an intermodulation distortion becomes large when the multi-frequency input level becomes high. Performs the function of suppressing the level. [0008] However, when the mobile station 8-2 existing around the service area 9-2 is capable of talking or during a call, the mobile station located near the mobile station antenna 22 is in communication. When the communication starts at 8-1, since the input level of the relay amplifier 2 is high, the upstream amplifier of the relay amplifier 2 saturates or the AGC circuit for protecting the amplifier operates to reduce the gain, thereby causing the peripheral amplifier to move. The machine 8-2 is unable to talk or the call is interrupted. Since the antenna 22 is small in size, it is often manufactured as a patch antenna or the like and built into the device 2 in many cases. [0009] Since the service area 9-2 is narrow, the mobile station 8 naturally comes closer to the mobile station antenna 22 of the relay amplifier 2. At this time, the service area on the downstream side is 9-2, but the service area on the upstream side is 9-1 because the amplification gain of the uplink is reduced by the operation of the AGC, and the service area on the upstream side is outside the area 9-1. Of the mobile devices (8-2 to 8-n in this example) are disabled or disconnected. [0010] The relay amplifying apparatus is an apparatus for servicing a small area, but basically, a plurality of mobile stations must be available in the area. It is not preferable that another mobile station becomes unable to talk just by coming close to the mobile station antenna. [0011] Even if the propagation conditions between the base station 1 and the relay amplifying device 2 are somewhat good, the propagation loss is large because it is far from the service distance of the relay amplifying device 2. Under these conditions, if the base station transmission power and the mobile device transmission power are almost equal,
Naturally, it is self-evident that the upstream amplifier of the relay amplifier is saturated. SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems in the conventional system for dealing with blind spots in a narrow area, to eliminate places with poor service quality and blind spots in a narrow area, and to reduce the size of a relay device. When the mobile station approaches the antenna of the relay amplifier, the economy of the mobile station is reduced (power saving), and the gain of the up-amplifying unit is reduced, so that the effective service area is narrowed. An object of the present invention is to provide a relay amplification system which has solved the disadvantages. [0013] A relay amplification system according to the present invention provides a bidirectional relay amplification of an intercommunication radio wave between a radio base station and a mobile station located in a dead zone in a service area of the radio base station. in the relay amplification system which comprises at least two relay amplifier having AGC circuit within the dead zone, at least two relay amplification <br/> device having the AGC circuit, said two existing within the dead zone One relay amplification
The service area common to the two devices
So that both cover at least two
To one of the at least one relay amplification instrumentation <br/> location painter bar dead fabric part or the speech quality deterioration area by electromagnetic interference present in the service area of another relay amplifier of the repeater amplifier device Arranged in the at least two
The relay amplification device is for the radio base station and for the mobile station.
In order for the diversity method to work at the same time,
Mobile station close to one of the at least two repeater amplifiers
When a call is made, the AG of the one relay amplification device is
The linearity of the amplifier of the one relay amplifying device is improved by the C circuit.
It was configured to reduce the output level to keep . FIG. 3 is a block diagram showing an embodiment of the present invention. In the figure, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals. 2-1 and 2-2 are relay amplifiers,
21-1 and 21-2 are base station antennas, 22-1 and 22-2.
2-2 is an antenna for blind areas (for mobile stations), 9-3-1,
9-3-2 indicates two relay amplifiers 2-1 and 2-
The service area 2 is an area covered by both 9-3-1 and 9-3-2. According to the present invention, when one relay amplifying device 2-1 is installed in the entire service area 9-2, in the service area 9-2, a dead area or communication quality caused by the radio wave obstacle 10 is provided. The relay amplifying device 2-2 is provided at a position where a part of the area is overlapped for the deteriorated area 9-4. By doing this,
By the service area 9-3-2 of the relay device 2-2, it is possible to eliminate a blind spot or a communication quality deterioration area 9-4 in the case of the conventional single relay device 2-1 in the single relay system. Both antennas for the base station and the mobile station each have two antennas, and a diversity effect can be obtained. Conventionally, a base station and a mobile station employ a diversity reception system to compensate for a decrease in line quality due to multipath. However, in the repeater, the diversity method was not adopted for economic reasons, and the output was increased. In particular, in the system targeted by the present invention, in order to economically install a small area in a building, a base station antenna is installed on a wall or a roof having a low ground level directly subjected to multipath fading, and a service is provided. The quality of area 9-2 was originally not good. According to the present invention, the diversity effect (usually 5 to 7)
Since the two-branch diversity system, which is said to be improved in dB, is obtained, the output of each relay device may be small, so that there is an advantage that the price of each relay device can be reduced. In the case of a common amplification type, the repeater amplifies multiple frequencies at the same time, so that linearity is required. High-output transistors are used to increase linearity, but if the output level is low, low-cost transistors can be used and power consumption can be reduced, contributing to simplification of the relay device. become. Next, as shown in FIG. 4, when the mobile station 8-1 starts a call in proximity to one of the relay devices 2-1, the AGC operation of the relay device 2-1 works, and Area 9-3-1 is reduced to an area 9-3-1 '. In this case, in the conventional single repeater system, the mobile station 8
In the present invention, the mobile unit 8-2 is in the area of the other relay device 2-2, but the call is possible. In the above embodiment, the case where two relay devices are installed for one service area has been described. It is clear that As described in detail above, the following effects can be obtained by implementing the present invention. (1) It is possible to eliminate the occurrence of a dead area or a call quality deterioration area due to an obstacle or the like in a small area dead area. (2) Since the diversity effect is obtained for both the uplink and the downlink, the output of the relay device can be reduced, and downsizing by power saving can be realized. (3) Using a mobile station near one of the relay devices,
Even if the zone contraction by C occurs, the other mobile units are in the zone of the other relay device, and can talk without being affected by the other mobile units.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration example of a conventional relay amplification system. FIG. 2 is a configuration example diagram of a conventional relay amplifying device. FIG. 3 is a configuration diagram showing an embodiment of the present invention. FIG. 4 is an explanatory diagram of another operation of the embodiment of the present invention. [Description of Signs] 1 Base station 11 Base station transmitting / receiving antenna 2 Relay amplifying device 21 Base station antenna 22 Mobile station antenna 23 Transmitting antenna 24 Combiner 25 Distributors 8-1 to 8-n Mobile units 81-1 to 8-1 81-n Mobile unit antenna 9-2 Required service area 9-1 Service area when AGC operates 10 Radio obstacle in small area 9-4 Dead area due to radio obstacle or communication quality degradation area 31 Base station Duplexer 32 Mobile station duplexer 33 Transmission filter 40 Downlink AGC ATT 50 Uplink AGC ATT 41 Downlink relay amplifier 51 Uplink relay amplifier 42 Downlink directional coupler 52 Uplink directional coupler 43 Downlink detection rectifier 53 Uplink detection rectifier 44 Downlink AGC control unit 54 Uplink AGC controller 55 Common amplifier

──────────────────────────────────────────────────の Continued on the front page (72) Inventor Noriyuki Kagaya 3-14-20 Higashinakano, Nakano-ku, Tokyo International Electric Company (72) Inventor Takashi Uchida 3-14-20 Higashinakano, Nakano-ku, Tokyo Country Tokio Electric Co., Ltd. (72) Inventor Hirofumi Masuda 3-14-20 Higashinakano, Nakano-ku, Tokyo Kokusai Electric Co., Ltd.Tokyo Ochiai Tokio Ochiai 3-14-20, Higashinakano, Nakano-ku, Tokyo Kokusai Electric Incorporated (72) Inventor Masakatsu Yamazaki 2-1-1 Toranomon, Minato-ku, Tokyo NTT Mobile Communication Network Inc. (56) References JP-A-62-207035 (JP, A) 1988-19925 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (1)

(57) [Claim 1] In a relay amplification system for bidirectionally relaying and amplifying an intercommunication radio wave between a radio base station and a mobile station located in a dead zone in a service area of the radio base station, At least two relay amplifiers having an AGC circuit in the dead zone, at least having the AGC circuit
The two repeater amplifiers are located in the dead zone.
The common service area of the two repeater amplifiers
So that both of the relay amplifying devices of
At least dead spots partially or call quality deterioration area to another at least a electromagnetic interference that is present within the service area of one relay amplification <br/> device of the two relay amplification device
One of which is arranged to relay amplification apparatus painter bar, the at least two relay amplification apparatus, said radio base station
Diversity scheme works for mobile and mobile stations
The mobile station further comprises the at least two relay amplifying devices.
When a call is made in close proximity to one of the
Amplification of the one repeater amplification device by the AGC circuit of the device
Relay amplification system in you characterized in that it is configured to reduce the output level to maintain the linearity of the vessel.