JP2001094509A - Radio communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system by allowing one base station to accommodate many subscriber stations by properly controlling thermal noise generated in each subscriber station. SOLUTION: The radio communication system has the base station 100 and subscriber stations 200 which are connected to the base station 100 via radio wave and each subscriber station 200 has an indoor unit 210 and an outdoor unit 220 which is connected to the indoor unit 210 through a coaxial cable; and a transmission frequency conversion part 214 of the indoor unit 220 is provided with a variable gain means which varies the gain of a transmitted signal corresponding to the distance to the base station 100.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio communication system comprising a base station and a plurality of subscriber stations, and more particularly to a radio communication system comprising a plurality of subscriber stations by suppressing thermal noise generated from the subscriber stations. The present invention relates to a wireless communication system capable of accommodating.

[0002]

2. Description of the Related Art Conventionally, in a radio communication system composed of a base station and a plurality of subscriber stations, the subscriber station includes an IDU.
(Indoor unit) and ODU (outdoor unit). Here, the IDU mainly has a modulation / demodulation function, and the ODU has a function of converting an IF (intermediate frequency) signal transmitted from the IDU into a radio frequency and amplifying it. The ODU and the IDU are connected by a coaxial cable.

[0003] In the above configuration, the uplink from the subscriber station to the base station employs a time division multiple access system. In this case, each subscriber station performs burst control (on / off control) of an IF signal by an IDU. The burst-controlled IF signal is converted into a transmission frequency by the ODU, amplified with a fixed gain, and then transmitted to the base station in a burst wave.

[0004] Incidentally, the ODU and the IDU are interconnected by a coaxial cable or the like as described above.
The IF signal subjected to the burst control is supplied to the ODU via the coaxial cable. However, when the IF signal propagates through the coaxial cable, a considerable transmission loss occurs.
For this reason, in the ODU, the transmission output is obtained by amplifying the transmission loss including the transmission loss by the coaxial cable, and the amplification gain in the ODU tends to increase.

Since the uplink from the subscriber station to the base station uses the time division multiple access method as described above,
The DU always operates the amplification function with a fixed gain regardless of whether the burst is on or off.

Therefore, while the burst is turned off by the IDU, the amplification function is working in the ODU. As a result, thermal noise is generated from the ODU when the burst is turned off. Here, if the amplification gain of the ODU is large, the thermal noise output from the ODU cannot be ignored.

That is, when a certain subscriber station turns on the burst wave, the other subscriber station turns off the burst wave because of the time division multiple access method, but each subscriber station arriving at the base station is turned off. The thermal noise from the subscriber station is integrated by the number of subscriber stations whose burst waves are turned off, and the signal ratio C / N between the signal and the thermal noise in the base station increases.

As a result, a problem arises in that the number of subscriber stations that can be accommodated in one base station is limited by thermal noise arriving at the base station from each subscriber station.

By the way, since the thermal noise generated from each subscriber station is conventionally amplified with a fixed gain in the ODU, it is basically the same in every subscriber station.
Of particular concern as a source of thermal noise is thermal noise from a subscriber station located close to the base station.
This is because a propagation distance to a base station is short in a subscriber station installed close to the base station, so the propagation loss is correspondingly small, and when viewed from the receiving end of the base station, it is compared with a distant subscriber station. This is because the amount of thermal noise from nearby subscriber stations increases.

[0010]

As described above, in this type of conventional radio communication system, for example, when a certain subscriber station turns on a burst wave, the remaining subscriber stations turn off the burst wave. However, the thermal noise from the subscriber station arriving at the base station is integrated by the number of the subscriber stations, thereby increasing the signal ratio C / N between the signal and the thermal noise. There is a problem that the number of subscriber stations that can be connected is limited.

Therefore, the present invention provides a radio communication system in which one base station can accommodate a large number of subscriber stations by appropriately controlling thermal noise generated from each subscriber station. The purpose is to provide.

[0012]

In order to achieve the above object, the invention according to claim 1 has a base station and a plurality of subscriber stations wirelessly connected to the base station. A wireless communication system having an indoor unit and an outdoor unit connected to the indoor unit via a coaxial cable, wherein the outdoor unit varies a gain of a transmission signal in accordance with a distance between the indoor unit and the base station. A gain varying means is provided.

According to a second aspect of the present invention, there is provided a base station and a plurality of subscriber stations wirelessly connected to the base station, wherein the subscriber station has an indoor unit and a coaxial cable connected to the indoor unit. A wireless communication system having an outdoor unit connected via a wireless communication system, wherein the base station includes: a delay amount measuring unit that measures a delay amount of a burst signal arriving from the subscriber station; And a delay amount notifying unit for notifying the subscriber station of the delay amount of the transmission unit, wherein each of the subscriber stations transmits a signal transmitted from the outdoor unit based on the delay amount notified by the delay amount notifying unit. It is characterized by comprising gain varying means for varying the gain of the signal.

[0014] According to a third aspect of the present invention, in the second aspect of the invention, the delay amount measuring means is provided in a frame signal from the subscriber station included in a baseband signal generated from the burst signal. Frame synchronization means for detecting a predetermined synchronization position, and measurement means for measuring the amount of delay of the burst signal by comparing the synchronization position detected by the frame synchronization means with a reference signal.
It is characterized by having.

According to a fourth aspect of the present invention, in the second aspect of the present invention, the delay amount notifying means sends a signal indicating the delay amount of the burst signal measured by the delay amount measuring means to the subscriber station. And notifies the subscriber station by notifying the subscriber station.

According to a fifth aspect of the present invention, in the second aspect of the invention, the gain varying means separates the signal indicating the delay amount from a downlink main signal from the base station addressed to the subscriber station. And a gain control means for varying a gain of a transmission signal transmitted from the outdoor unit based on the signal indicating the delay amount separated by the separation means.

The invention according to claim 6 has a base station and a plurality of subscriber stations wirelessly connected to the base station, wherein the subscriber station has an indoor unit and a coaxial cable connected to the indoor unit. A wireless communication system having an outdoor unit connected through a wireless communication system, wherein each of the subscriber stations includes a level detector for detecting a reception level of a downlink signal from the base station, and a reception level detected by the level detector. Gain variable means for varying the gain of the transmission signal transmitted from the outdoor unit based on

According to a seventh aspect of the present invention, in the sixth aspect of the present invention, the reception level detecting means adjusts the reception level based on a level of an intermediate frequency signal generated from a downlink signal from the base station. It is characterized by detecting.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the radio communication system according to the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a first embodiment of the radio communication system according to the present invention.

Referring to FIG. 1, the wireless communication system includes:
It comprises a base station 100 and a plurality of subscriber stations 200 connected to the base station 100 via a radio line. In FIG. 1, one of the plurality of subscriber stations 200 is shown.

In FIG. 1, base station 100 includes transmission signal multiplexing section 111, modulation section 112, transmission frequency conversion section 11
3, antenna duplexer 114, antenna 115, reception frequency conversion unit 116, demodulator 117, reception signal separation unit 11
8, the frame signal synchronizing unit 119, the phase comparing unit 120,
The control unit 121 is provided.

The subscriber station 200 is connected to the subscriber station ODU.
210 and this subscriber station ODU 210 to the coaxial cable 23
0, and the subscriber station ODU 210 includes an antenna 211, an antenna duplexer 212, a reception frequency conversion unit 213, and a transmission frequency conversion unit 214. Station IDU2
20 includes a modulation unit 221, a reception signal separation unit 222, a transmission signal multiplexing unit 223, a modulation unit 224, and a control unit 225.

In the above configuration, the transmission baseband signal supplied to the transmission signal multiplexing unit 223 of the subscriber station IDU 220 of the subscriber station 200 is subjected to synchronous multiplex conversion processing so as to fit into a predetermined time slot in a transmission burst. ,
After being supplied to the modulation unit 224 and subjected to modulation processing, the IF
The signal (burst signal) is supplied to the transmission frequency converter 214 of the subscriber station ODU 210 via the coaxial cable 230. In the transmission frequency converter 214, the supplied IF signal is frequency-converted, amplified with a predetermined gain, and transmitted to the base station 100 as an uplink burst signal via the antenna duplexer 212 and the antenna 211. .

On the other hand, in the base station 100, the antenna 1
The uplink burst signal (RF signal) from the subscriber station 200 received at 14 is supplied to the reception frequency converter 116 via the antenna duplexer 114. Receive frequency converter 11
At 6, the burst signal (RF signal) is subjected to frequency conversion, amplified with a predetermined gain, and supplied as an IF signal (burst signal) to the demodulator 117, where demodulation processing is performed and the baseband signal Is generated.

The baseband signal generated by the demodulator 117 is supplied to a frame signal synchronizing unit 119, and is a predetermined synchronization position in a frame signal contained in a predetermined time slot of the baseband signal, for example, a reference burst position. Is detected.

The reference burst position detected by the frame signal synchronizing section 119 is compared with a preset reference signal by the phase comparing section 120 to obtain a phase difference signal.

The phase difference signal obtained by the phase comparing section 120 is supplied to the transmission signal multiplexing section 111 via the control section 121. In the transmission signal multiplexing unit 111, the phase comparison unit 12
0 is interpolated into the downlink main signal of the transmission baseband signal, synchronous multiplex conversion processing is performed so as to fit in a predetermined time slot in the transmission signal, and the modulation unit 112
To supply.

Then, after the modulation processing is performed by the modulation section 112, the signal is supplied to the transmission frequency conversion section 113 as an IF signal.
The frequency conversion is performed on the F signal, and the signal is amplified with a predetermined gain.
An RF signal is transmitted to the subscriber station 200.

In the subscriber station 200, the antenna 21
1 is supplied to the reception frequency conversion unit 213 via the antenna duplexer 212 with the interpolated phase difference signal from the base station 100 received by the base station 100.
The signal is subjected to frequency conversion, amplified with a predetermined gain, and supplied to the demodulation unit 221 via the coaxial cable 230 as an IF signal. The demodulation section 221 demodulates the IF signal and supplies the IF signal to the received signal separation section 222 as a baseband signal, and separates the phase difference signal interpolated in the downlink main signal from the downlink main signal. Is done.

The phase difference signal separated by the received signal separation unit 222 is supplied to the transmission frequency conversion unit 214 of the subscriber station ODU 210 via the control unit 225, and controls the transmission gain of the transmission frequency conversion unit 214.

Here, the control unit 225 estimates the distance between the subscriber station 200 and the base station 100 based on the phase difference signal supplied from the received signal separation unit 222, and
The transmission gain in the transmission frequency conversion unit 214 is controlled so that the transmission gain becomes smaller as the subscriber station 200 is located closer to 00.

That is, as the subscriber station 200 is located farther from the base station 100, the delay amount of the burst wave arriving at the base station 100 becomes larger. Corresponding to the distance between Therefore, based on the amount of delay of this burst wave,
Based on the farthest subscriber station 20, each subscriber station 200
From the subscriber station ODU of each subscriber station 200 such that the level of the received signal at the receiving end of the base station 100 from
The transmission gain of 210 is set.

Specifically, the phase comparison unit 1 of the base station 100
At 20, the delay amount of the burst wave arriving from each subscriber 200 is detected as a phase difference signal, and the control unit 121 of the base station 100 transmits the phase difference signal from the base station 100 to the subscriber station 200. By interpolating into the main signal, the signal is transferred to the subscriber station 200.

In the subscriber station 200, the phase difference signal interpolated into the main signal is separately obtained, and the control unit 225 of the subscriber station 200 determines the base station 100 and the subscriber station 200 based on the phase difference signal. The distance between each of the subscriber stations 200 and the base station 100 is estimated with reference to the distance from the base station 100 of the farthest subscriber station 200 acquired and stored in advance. The gain of the ODU 210 is set based on the distance and the corresponding propagation loss.

According to such a configuration, the level of the signal received from each subscriber station 200 at the receiving end of the base station 100 is reduced by the subscriber station 20 installed near the base station 100.
0 and the subscriber station 200 installed at a position far from the base station 100, so that the thermal noise received from each subscriber station 200, especially Since the thermal noise received from the subscriber station 200 installed at a close position can be reduced, the total thermal noise received by the base station 100 is reduced, and as a result,
The number of subscriber stations 200 that can be connected to one base station 100 can be increased.

In the above description, the base station 100 only detects the delay amount of the burst wave arriving from each subscriber station 200, and the processing for obtaining the propagation loss from this delay amount is performed in each subscriber station 200. The base station 1
The processing for obtaining the propagation loss may be performed on the 00 side, and the result may be transferred to each subscriber station 200.

As described above, according to the radio communication system of this embodiment, the base station 100 and the plurality of subscriber stations 200 wirelessly connected to the base station 100 are provided.
00 is an outdoor unit 22 in a wireless communication system having an indoor unit 210 and an outdoor unit 220 connected to the indoor unit 210 via a coaxial cable.
Since the transmission frequency conversion unit 214 of 0 is provided with a variable gain means for varying the gain of a transmission signal in accordance with the distance to the base station 100, the sum of the thermal noise received by the base station 100 is calculated. As a result, the number of subscriber stations 200 that can be connected to one base station 100 can be increased.

Next, a second embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a block diagram showing a second embodiment of the radio communication system according to the present invention.

FIG. 2 is a block diagram showing a basic configuration of a wireless communication system according to a second embodiment of the present invention.

In the second embodiment shown in FIG.
The subscriber station 200 detects the level of the received signal received from the base station 100, and estimates the distance between the base station 100 and the subscriber station 200 based on the detected level. Then, based on the farthest subscriber station 200, the base station 10
From the distance difference between 0 and the subscriber station 200, a corresponding difference in propagation loss is calculated, and the gain of the subscriber station ODU 210 is set according to the calculated value.

In FIG. 2, the same operation as in the first embodiment shown in FIG.
The same reference numerals as those used in are used.

Referring to FIG. 2, the wireless communication system includes:
It comprises a base station 100 and a plurality of subscriber stations 200 connected to the base station 100 via a radio line. In FIG. 2, one of the plurality of subscriber stations 200 is also shown.
One is shown.

In FIG. 2, base station 100 includes transmission signal multiplexing section 111, modulation section 112, transmission frequency conversion section 11
3. Antenna duplexer 114, antenna 115, reception frequency conversion unit 116, demodulator 117, reception signal separation unit 118
It comprises.

The subscriber station 200 is connected to the subscriber station ODU.
210 and this subscriber station ODU 210 to the coaxial cable 23
0, and the subscriber station ODU 210 includes an antenna 211, an antenna duplexer 212, a reception frequency conversion unit 213, and a transmission frequency conversion unit 214. Station IDU2
20 includes a modulation unit 221, a reception signal separation unit 222, a transmission signal multiplexing unit 223, a modulation unit 224, a control unit 225, and a level detection unit 226.

In the above configuration, the transmission baseband signal supplied to the transmission signal multiplexing section 223 of the subscriber station IDU 220 of the subscriber station 200 is subjected to synchronous multiplex conversion processing so as to fit into a predetermined time slot in a transmission burst. ,
After being supplied to the modulation unit 224 and subjected to modulation processing, the IF
The signal (burst signal) is supplied to the transmission frequency converter 214 of the subscriber station ODU 210 via the coaxial cable 230. In the transmission frequency converter 214, the supplied IF signal is frequency-converted, amplified with a predetermined gain, and transmitted to the base station 100 as an uplink burst signal via the antenna duplexer 212 and the antenna 211. .

On the other hand, in the base station 100, the antenna 1
The uplink burst signal (RF signal) from the subscriber station 200 received at 14 is supplied to the reception frequency converter 116 via the antenna duplexer 114. Receive frequency converter 11
At 6, the burst signal (RF signal) is subjected to frequency conversion, amplified with a predetermined gain, and supplied as an IF signal (burst signal) to the demodulator 117, where demodulation processing is performed and the baseband signal Is generated.

In base station 100, the downlink main signal supplied to transmission signal multiplexing section 111 is subjected to synchronous multiplex conversion processing so that it falls within a predetermined time slot in the transmission signal, and supplied to modulation section 112. After being subjected to modulation processing, the signal is supplied to the transmission frequency conversion unit 113 as an IF signal. In the transmission frequency converter 113, the supplied IF
The signal is subjected to frequency conversion, amplified with a predetermined gain, and transmitted to the subscriber station 200 as a downlink burst signal via the antenna duplexer 114 and the antenna 115.

In the subscriber station 200, the antenna 21
The RF signal received from the base station 100 received in step 1 is supplied to the reception frequency conversion unit 213 via the antenna duplexer 212, where the supplied RF signal is frequency-converted and has a predetermined gain. The signal is amplified and supplied to the demodulation unit 221 via the coaxial cable 230 as an IF signal. The demodulation section 221 performs a demodulation process on the IF signal, and converts the IF signal into a baseband signal.
22 and the downstream main signal is separated.

The IF signal supplied to the demodulator 221 is supplied to a level detector 226, where it is subjected to detection processing, converted into a voltage, and applied to the controller 225 as a level signal.

Here, the control unit 225 estimates the distance between the subscriber station 200 and the base station 100 based on the level signal supplied from the level detection unit 226, and
The transmission gain in the transmission frequency conversion unit 214 is controlled so that the transmission gain becomes smaller as the subscriber station 200 is located closer to zero.

That is, the level of the signal received from the base station 100 decreases as the subscriber station 200 is located farther from the base station 100, and the level of the signal received from the base station 100 is smaller than that of the base station 100 and the subscriber. The distance corresponds to the distance from the station 200.

Therefore, in the second embodiment, each subscriber station 2 is set on the basis of the level of the signal received from the base station 100 with reference to the farthest subscriber station 20.
00 so that the level of the received signal at the receiving end of the base station 100 is the same.
The transmission gain of the DU 210 is set.

More specifically, in the subscriber station 200, the level of the signal received from the base station 100 is detected by the level detector 22.
6, the distance between the base station 100 and the subscriber station 200 is estimated based on the level signal output from the level detection unit 226, and the farthest end subscriber station 200 acquired and stored in advance is stored. Of the subscriber station ODU2 based on the estimated distance between each subscriber station 200 and the base station 100 and the corresponding propagation loss based on the distance from the base station 100 to the subscriber station ODU2.
Set a gain of 10.

According to such a configuration, the level of the signal received from each subscriber station 200 at the receiving end of the base station 100 is reduced by the subscriber station 20 installed near the base station 100.
0 and the subscriber station 200 installed at a position far from the base station 100, so that the thermal noise received from each subscriber station 200, especially Since the thermal noise received from the subscriber station 200 installed at a close position can be reduced, the total thermal noise received by the base station 100 is reduced, and as a result,
The number of subscriber stations 200 that can be connected to one base station 100 can be increased.

In the above description, it has been described that the level detection of the downlink IF signal and the control of the gain of the transmission frequency converter 214 are performed by the subscriber station IDU 220, but the configuration is such that the control is performed within the subscriber station ODU 210. May be.

[0058]

As described above, according to the present invention, there are provided a base station and a plurality of subscriber stations wirelessly connected to the base station, wherein the subscriber station comprises an indoor unit and the indoor unit. A wireless communication system having an outdoor unit connected to the outdoor unit via a coaxial cable, wherein the outdoor unit is provided with a gain variable unit that varies a gain of a transmission signal in accordance with a distance between the outdoor unit and the base station. Because we configured
The thermal noise generated from the subscriber station ODU of each subscriber station can be reduced, and the base station in the wireless communication system according to the present invention is determined based on the farthest end of the cell radius served by the base station. OD of the subscriber station installed at a position close to
By reducing the gain of U, it is possible to make the thermal noise supplied from each subscriber station at the receiving end of the base station almost the same level, thereby reducing the thermal noise received by the base station. Can be reduced, and as a result, the number of subscriber stations that can be connected to one base station can be increased.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a wireless communication system according to the present invention.

FIG. 2 is a block diagram showing a second embodiment of the wireless communication system according to the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 100 base station 111 transmission signal multiplexing unit 112 modulation unit 113 transmission frequency conversion unit 114 antenna duplexer 115 antenna 116 reception frequency conversion unit 117 demodulator 118 reception signal separation unit 119 frame signal synchronization unit 120 phase comparison unit 121 control unit 200 subscription Subscriber station 210 subscriber station ODU 211 antenna 212 antenna duplexer 213 reception frequency conversion unit 214 transmission frequency conversion unit 220 subscriber station IDU 221 modulation unit 222 reception signal separation unit 223 transmission signal multiplexing unit 224 modulation unit 225 control unit 226 level detection Part 230 Coaxial cable

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[Procedure amendment]

[Submission date] September 30, 1999 (September 9, 1999
0)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Name of invention

[Correction method] Change

[Correction contents]

[Title of the Invention] Wireless communication system

Claims (7)

[Claims] An indoor unit and an outdoor unit connected to the indoor unit via a coaxial cable, comprising a base station and a plurality of subscriber stations wirelessly connected to the base station. The wireless communication system according to claim 1, wherein the outdoor unit is provided with a gain varying unit that varies a gain of a transmission signal according to a distance from the base station. 2. A base station and a plurality of subscriber stations wirelessly connected to the base station, wherein the subscriber station includes an indoor unit and an outdoor unit connected to the indoor unit via a coaxial cable. In the wireless communication system having the above, the base station comprises: a delay amount measuring means for measuring a delay amount of a burst signal arriving from the subscriber station; and a delay amount of the burst signal measured by the delay amount measuring means. And each of the subscriber stations is configured to vary a gain of a transmission signal transmitted from the outdoor unit based on the delay amount notified by the delay amount notifying unit. A wireless communication system comprising means. 3. The delay amount measuring means includes: a frame synchronization means for detecting a predetermined synchronization position in a frame signal from the subscriber station included in a baseband signal generated from the burst signal; and the frame synchronization means. 3. The wireless communication system according to claim 2, further comprising: a measuring unit configured to measure a delay amount of the burst signal by comparing a synchronization position detected by the method with a reference signal. 4. The delay amount notifying means inserts a signal indicating a delay amount of the burst signal measured by the delay amount measuring means into a downlink main signal addressed to the subscriber station and notifies the subscriber station of the signal. The wireless communication system according to claim 2, wherein 5. The gain variable unit includes: a separating unit that separates a signal indicating the delay amount from a downlink main signal from the base station to the subscriber station; and a delay unit that separates the delay amount separated by the separating unit. The wireless communication system according to claim 2, further comprising: gain control means for varying a gain of a transmission signal transmitted from the outdoor unit based on the indicated signal. 6. A base station and a plurality of subscriber stations wirelessly connected to the base station, wherein the subscriber station includes an indoor unit and an outdoor unit connected to the indoor unit via a coaxial cable. In the wireless communication system having the above, each of the subscriber stations, a level detection means for detecting a reception level of a downlink signal from the base station, a transmission from the outdoor unit based on the reception level detected by the level detection means A variable gain means for varying the gain of the transmission signal to be transmitted. 7. The wireless communication system according to claim 6, wherein said reception level detection means detects said reception level based on a level of an intermediate frequency signal generated from a downlink signal from said base station.