JP3322220B2 - Subscriber wireless communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a subscriber wireless communication system mainly using a communication device.

[0002]

2. Description of the Related Art With the advance of advanced information technology, the amount of information communication has rapidly increased, and the content of information has been diversified, such as telephones, faxes, data, images, and the like. . However, existing communication networks mainly using metallic cables cannot adequately cope with large-scale and diverse information and communication needs, and optical fiber cables have sufficient transmission capacity, but cost, land use, etc. Because of the many restrictions, maintenance is not always quick. For these reasons, with the advancement of communication networks, high-speed, low-cost,
There is a need for the development and commercialization of wireless systems with wider bandwidths. The subscriber wireless communication system is a wireless communication system that is expected to be used more effectively in the future from the above-mentioned viewpoints, and a wireless circuit connects between a base station in the network and a user's building. It is what ties.

FIG. 9 shows an example of a system configuration of a subscriber radio communication system. Reference numeral 1 denotes a base station, which comprises a transmitting / receiving antenna 2 and a base station communication device 3. Reference numeral 4 denotes a subscriber station, which includes a transmitting / receiving antenna 5 and a subscriber station communication device 6. Reference numeral 7 denotes a radio signal between the base station and the subscriber station, and reference numeral 8 denotes an optical fiber relay transmission line connected to a network such as a public network.

Next, the operation will be described. One end of the base station communication device 3 of the base station 1 is connected to the network by an optical fiber relay transmission line 8, and transmits information from the subscriber station 4 to the network side via the optical fiber relay transmission line 8. Information to the subscriber station 4 is received via the optical fiber relay transmission line 8. The other end is a transmitting / receiving antenna 2 capable of efficiently transmitting / receiving a radio signal 7 to / from the subscriber station 4.
, And converts information to be transmitted to the subscriber station 4 into a radio signal 7. Also, it converts the reception of the radio signal 7 from the subscriber station 4 into an optical signal and transmits it to the network. One end of the subscriber station communication device 6 of the subscriber station 4 is connected to the transmitting / receiving antenna 5 that can efficiently transmit and receive the radio signal 7, and the other end is connected to the subscriber station terminal. The signal is converted into a radio signal 7 and transmitted to the transmission / reception antenna 5, and information of the radio signal 7 received by the transmission / reception antenna 5 is transmitted to the subscriber station terminal.

[0005] The configuration of the base station 1 and the subscriber station 4 is such that the base station 1 transmits a radio signal 7 carrying information to all the subscriber stations 4 to a certain subscriber station 2, The subscriber station 2 retrieves only its own information and sends it to another subscriber station 4
A point-to-point configuration for transmitting information to all subscriber stations 4 by transmitting a radio signal 7 from the base station 1 to the A radio signal 7 carrying the information is transmitted to all the subscriber stations 4, and each subscriber station 4 has a point-to-multipoint configuration in which only its own information is taken out.

FIG. 10 shows an example of the configuration of the subscriber station communication device 6, where 9 is a reception wave, and the transmission / reception antenna 5
Is input to the receiving unit 10. An output terminal of the receiving unit 10 is connected to the interface processing unit 11 and transmits a reception signal 12. The interface processing unit 11 is also connected to an input terminal of the transmission unit 13 and transmits a transmission signal 14.
The output end of the transmitting unit 13 is connected to the transmitting / receiving antenna 5 and transmits the transmitting wave 15. Interface processing unit 1
1 is terminated at the subscriber station terminal device, and transmits and receives information for the subscriber station terminal device as a terminal signal 16.

Next, the operation will be described. The radio signal 7 received by the transmission / reception antenna 5 is subjected to demodulation and the like by the reception unit 10 as a reception wave 9, and is transmitted to the interface processing unit 11 as a reception signal 12. The interface processing unit 11 converts the information from the network into an appropriate form for transmission to the subscriber terminal device, and transmits the information to the network as a transmission signal 14 in an appropriate form.
Send to 3. The transmitting unit 13 performs modulation and the like,
5 and transmitted to the transmitting / receiving antenna 5.

[0008]

The conventional subscriber radio communication system is configured as described above. When an antenna is installed, the level of the line is adjusted, the reception intensity of an adjacent frequency is measured, and the like. Although it is installed in a line state, if another communication system enters a line near the own subscriber's wireless communication system after that, if an interference wave is input to its own transmitting / receiving antenna, it will be different from the time of installation. And the line quality deteriorates.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and measures the reception strength of adjacent frequencies and transmits the measured reception strength to the base station so that each base station can receive a signal from each subscriber station. The purpose is to monitor the interference state.

[0010]

According to a first aspect of the present invention, there is provided a subscriber wireless communication system having an interference detecting unit capable of detecting a received electric field strength of an adjacent frequency in a subscriber station communication apparatus, and using the interference detecting unit as interference information. By transmitting to the station, it was possible for the base station to monitor the state of interference of each subscriber station.

[0011] A subscriber wireless communication system according to a second aspect of the present invention provides an interference detection unit capable of detecting the reception strength of an adjacent frequency in a subscriber station communication apparatus, and outputs a corresponding value of leakage power from the adjacent frequency. By having the means, it is possible to transmit the leaked power from the adjacent frequency to the base station, and to monitor the state of the leaked power from the adjacent frequency of each subscriber station in the base station.

A subscriber wireless communication system according to a third aspect of the present invention has an AGC amplifier in a subscriber station communication apparatus, and receives amplitude waves A by receiving received waves of adjacent frequencies.
The GC voltage can be obtained and transmitted to the base station as interference information, thereby enabling the base station to monitor the state of interference of each subscriber station.

A subscriber radio communication system according to a fourth aspect of the present invention has a detector constituted by a diode in a subscriber station communication device, and receives a reception wave of an adjacent frequency to detect a detection voltage as amplitude information. By transmitting the interference information to the base station as interference information, the base station can monitor the state of interference of each subscriber station.

The subscriber radio communication system according to the fifth invention uses an AGC amplifier in a demodulation unit in the subscriber station communication device, thereby receiving a reception wave of an adjacent frequency when communication is not being performed, thereby obtaining an amplitude. The reception intensity of an adjacent frequency can be obtained from the AGC voltage, which is information, and is transmitted to the base station as interference information, so that the base station can monitor the state of interference of each subscriber station.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 The configuration of the subscriber wireless communication system according to the first embodiment of the present invention is the same as that of the related art, and has the configuration shown in FIG.
In the figures, the same numbers as those in the other figures are the same.

The configuration of the subscriber station communication apparatus according to the first embodiment of the present invention has the configuration shown in FIG. The receiving wave 9 is transmitted from the transmitting / receiving antenna 5 to the receiving unit 1 for demodulation and the like.
7 is input. The output end of the receiving unit 17 is connected to the interface processing unit 11 and transmits a received signal 12 obtained by demodulating the received wave 9. The receiving unit 17 is also connected to an interference detecting unit 18 that can detect the reception intensity of a frequency component adjacent to the frequency used by itself, and outputs a frequency-converted received wave 19 described later. The interface processing unit 11 functions as a mechanical and electrical interface with the subscriber station terminal device. The interface processing unit 11 is also connected to an input end of a transmission unit 20 that performs modulation and the like, and converts a signal from the subscriber station terminal device. Then, it transmits as a transmission signal 14. The transmission unit 20 is also connected to the interference detection unit 18, and the interference detection unit 18 detects the reception intensity of an adjacent frequency component from the input frequency-converted reception wave 19, and transmits it as interference information 21. The transmission unit 20 transmits the interference information 21
Is modulated together with the transmission signal 14, and the information is transmitted as a transmission wave 15 as a radio wave to the transmission / reception antenna 5 to which the output terminal is connected. The interface processing unit 11 is terminated at the subscriber station terminal device, and transmits and receives a terminal signal 16 as information to and from the subscriber station terminal device.

The receiving section 17 includes an amplifying section 22 for amplifying an input signal, a frequency converting section 23 for converting a frequency of the input signal, and a distribution section 24 for distributing and outputting the input signal. And a demodulation unit 25 for demodulating information from the input modulation signal. The reception wave 9 is input to the amplification unit 22, and the amplified reception wave 9 is
6 is input to the frequency conversion unit 23. An output terminal of the frequency conversion unit 23 is connected to an input terminal of the distribution unit 24,
The signal is transmitted as a received wave 19 after frequency conversion after the desired frequency conversion. The distribution unit 24 includes the interference detection unit 18 and the demodulation unit 2
5 and transmits the received frequency-converted received waves 19 respectively. The demodulation unit 25 is connected to the interface processing unit 11, and transmits the demodulated information as the reception signal 12.

The base station 1 receives the transmission wave 15 including the interference information 21 from each subscriber station 4 and monitors the interference state of each subscriber station 4.

Embodiment 2 The configuration diagram of the subscriber station communication device according to the second embodiment of the present invention has the configuration shown in FIG. 2, and the reception intensity of the frequency component adjacent to the subscriber station communication device described in the first embodiment is determined in advance. This is a configuration in which a memory unit 27 holding leakage power obtained from a corresponding adjacent frequency to the own frequency by a method described later is added. The input end of the memory unit 27 is connected to the interference detection unit 18 and receives interference information 21 that is the reception intensity of an adjacent frequency component. In the memory unit 27, the value of the leakage power from the retained adjacent frequency to the own frequency corresponding to the input interference information 21 is transmitted to the transmission unit 20 and transmitted to the adjacent leakage power information 28.
In the figure, the same numbers as those in the other figures are the same.

The base station 1 receives the transmission wave 15 including the adjacent leakage power information 28 from each of the subscriber stations 4 and monitors the interference state of each of the subscriber stations 4.

FIG. 3 is a graph for explaining a method for obtaining the above-described leakage power from adjacent frequencies. 29 is the frequency spectrum of the transmission wave at the transmitter output end of the communication system used at a frequency adjacent to the frequency used by itself. Numeral 30 denotes the vertical axis of this graph, which represents the power (dBm), and numeral 31 denotes the horizontal axis, which represents the frequency (Hz). Reference numeral 32 denotes a frequency spectrum mask defined by a communication system used in adjacent frequencies.
33 is an adjacent frequency Fad (Hz) which is a center frequency of an adjacent frequency spectrum, and 34 is an own frequency Fm.
a (Hz). 35 is an adjacent frequency Fad (Hz)
33 and relative frequency difference X between own frequency Fma (Hz) 34
(DBc). If this relationship is known, the absolute value of the power of the frequency spectrum 29 changes even if the interference wave is received from another system, but the frequency spectrum mask 32
The relative power of the adjacent frequency Fad (Hz) 33 detected by the interference detection unit 18 and the relative power difference X (dBc) 35 indicate a relative power difference X (dBc) 35. You can ask. Therefore, by storing the reception power of the adjacent frequency Fad (Hz) 33 and the leakage power in the memory unit 27 in association with each other, it is possible to output the leakage power corresponding to the reception power.

The memory section 27 is not limited to the inside of the subscriber station communication device 6, but may be inside the base station communication device 3. Further, the relative power difference X is stored in the memory unit 27, and the difference between the reception intensity of the adjacent frequency detected by the interference detection unit 18 and the relative power difference X of the memory unit 27 is calculated and output by the calculation unit. May be.

Embodiment 3 FIG. FIG. 4 shows a configuration of a subscriber station communication apparatus according to Embodiment 3 of the present invention. In the figure, reference numeral 36 denotes an interference detection unit according to the third embodiment of the present invention. The configuration is the same as that described in the first embodiment, and the operation is also the same. The same numbers as those in the other drawings are the same.

FIG. 5 shows the configuration of the interference detection unit 36 according to the third embodiment of the present invention. Reference numeral 37 denotes a band pass filter. The input terminal is connected to the distribution unit 24 in FIG. 4, and the output terminal is connected to the input terminal of the AGC amplifier 38.
The output terminal of the AGC amplifier 38 is connected to the interference measurement unit 39, and the output terminal is connected to the transmission unit 20 in FIG.

The base station 1 receives the transmission wave 15 containing the interference information 21 from each of the subscriber stations 4 and monitors the interference state of each of the subscriber stations 4.

Next, the operation of the interference detector 36 will be described. The band-pass filter 37 passes only the band of the adjacent frequency after the frequency conversion by the frequency conversion unit 23 of FIG. 4 and blocks the passage of the other frequencies. The post-reception wave 19 is input, and an interference reception wave 40, which is a frequency component adjacent to the frequency-converted own frequency, is output to the output terminal. The interference reception wave 40 is input to the input terminal of the AGC amplifier 38. The AGC amplifier 38 is an amplifier that automatically changes the gain so as to keep the input amplitude at a constant amplitude, and transmits an AGC voltage 41 that is a voltage proportional to the gain to the interference measurement unit 39. The interference measuring unit 39 measures the voltage of the AGC voltage 41 and determines the AGC voltage 41 in advance.
The relationship between the gain with respect to power and the power with respect to a certain amplitude is measured in advance, the reception strength is obtained, and the
Send as

Embodiment 4 FIG. 6 shows a configuration of a subscriber station communication apparatus according to Embodiment 4 of the present invention. In the figure, reference numeral 42 denotes an interference detection unit according to the fourth embodiment of the present invention. The configuration is the same as that described in the first embodiment, and the operation is also the same. The same numbers as those in the other drawings are the same.

FIG. 7 shows the configuration of the interference detection unit 42 according to the fourth embodiment of the present invention. In the figure, reference numeral 43 denotes a diode detector, and the rest is the same as the interference detector 36 of the third embodiment, and the same reference numerals as those in the other figures denote the same parts. The input end of the bandpass filter 37 is connected to the distribution unit 24 in FIG. 6, and the output end is connected to the input end of the diode detection unit 43. The output end of the diode detection unit 43 is connected to the interference measurement unit 39, and the output end is connected to the transmission unit 20 in FIG.
Send

The base station 1 receives the transmission wave 15 including the interference information 21 from each of the subscriber stations 4 and monitors the interference state of each of the subscriber stations 4.

Next, the operation of the interference detecting section 42 will be described. The configuration other than the diode detector 43 is the same as the interference detector 36 shown in the third embodiment. Diode detector 43
Consists of a diode, a resistor, a capacitor, etc., and outputs a voltage proportional to the power of the input signal,
The interference reception wave 40 is input from the band-pass filter 37, and the detection voltage at 44 is transmitted to the interference measurement unit 39. The interference measurement unit 39 measures the voltage of the detection voltage 44 in proportion to the reception electric field intensity of the interference wave, measures the relationship between the voltage and the reception electric field intensity in advance, obtains the reception electric field intensity, and
0 is transmitted as interference information 21.

Embodiment 5 The constituent wave of the subscriber station communication device according to the fifth embodiment of the present invention has the structure shown in FIG. In the drawings, the same numbers as those in the other drawings are the same. The reception wave 9 is input from the transmission / reception antenna 5 to a reception unit 45 that performs demodulation and the like. The output end of the receiving unit 45 is connected to the interface processing unit 11 and transmits the received signal 12 obtained by demodulating the received wave 9. The receiving unit 45 is also connected to the interference measuring unit 39, and outputs the AGC voltage 41. The interface processing unit 11 functions as a mechanical and electrical interface with the subscriber station terminal device. The interface processing unit 11 is also connected to an input terminal of a transmission unit 20 that performs modulation and the like, and transmits a signal from the subscriber station terminal device. The signal is converted and transmitted as a transmission signal 14. The transmission unit 20 is also connected to the interference measurement unit 39, receives the interference information 21 that is the reception intensity of the adjacent frequency component detected from the AGC voltage 41, and modulates the interference information 21 together with the transmission signal 14. Further, the output terminal is connected to the transmitting / receiving antenna 5 and transmits information such as the transmission signal 14 and the interference information 21 as a transmission wave 15 which is a radio wave. The interface processing unit 11 is terminated at the subscriber station terminal device, and transmits and receives a terminal signal 16 as information to and from the subscriber station terminal device.

The base station 1 receives the transmission wave 15 including the interference information 21 from each subscriber station 4 and monitors the interference state of each subscriber station 4.

The receiving section 45 can determine whether the input signal is a signal for itself and the amplifying section 22 for amplifying the input signal. A frequency converter 46 that converts the own frequency into a frequency that can pass through a band-pass filter 47 described below, and if not for itself, converts an adjacent frequency into a frequency that can pass through the band-pass filter 47; A band-pass filter 47 having a pass band width for passing only a necessary band of the wave 9 and a demodulation unit 48 for demodulating information from the input modulation signal are provided. , The amplified received wave 9 is the amplified received wave 26
Is input to the frequency converter 46. Frequency converter 4
The output terminal 6 is connected to a band-pass filter 47. After performing the above-mentioned determination as to whether or not the signal is for itself, frequency conversion is performed, and the signal is transmitted as a frequency-converted received wave 19. An output terminal of the band-pass filter 47 is connected to a demodulation unit 48.
And transmits a band-limited reception wave 49 that has been band-limited. The demodulation unit 48 is connected to the interference measurement unit 39 and the interface processing unit 11, and transmits information obtained by demodulating the AGC voltage 41 to the interface processing unit 11 to the interference measurement unit 38 as the reception signal 12.

The demodulation section 48 is provided with the AGC amplifier 40
, And a demodulator 50, and a band-limited received wave 49 is input from a band-pass filter 47 to an input terminal of the AGC amplifier 40. When the band-limited received wave 49 is a signal for itself, the AGC amplifier 40 outputs an AGC output wave 51 amplified to a constant amplitude to the demodulator 50.
The demodulator 49 transmits information demodulated from the AGC output wave 51 to the interface processing unit 11 as a reception signal 12. When the band-limited reception wave 49 is not a signal for itself in the AGC amplifier 40, the AGC voltage 41 is output to the interference measurement unit 39.

[0035]

According to the first aspect of the present invention, the interference state of each subscriber station can be monitored at the base station, and the interference state from the initial installation state of the own system has changed due to the new installation of another system or the like. This can be monitored by the base station.

According to the second aspect, the state of the leakage power from the adjacent frequency of each subscriber station can be monitored in the base station,
The base station can monitor a change in the interference state from the initial installation state of the own system due to a new installation of another system or the like.

According to the third aspect, the interference state of each subscriber station can be monitored at the base station, and the interference state from the initial installation state of the own system due to the new installation of another system or the like is changed. It can be monitored at the base station.

According to the fourth aspect, the state of interference of each subscriber station can be monitored at the base station, and the fact that the interference state from the initial installation state of the own system has changed due to the new installation of another system or the like. It can be monitored at the base station.

According to the fifth aspect, the base station can monitor the state of interference of each subscriber station when communication is not being performed, and the base station can monitor the interference from the initial installation state of its own system due to new installation of another system or the like. The change in the interference state can be monitored by the base station, and the number of components can be reduced.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a subscriber station communication device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a subscriber station communication device according to a second embodiment of the present invention.

FIG. 3 is a graph for explaining a method for obtaining adjacent leakage power according to the second embodiment of the present invention.

FIG. 4 is a configuration diagram of a subscriber station communication device according to a third embodiment of the present invention.

FIG. 5 is a configuration diagram of an interference detection unit according to a third embodiment of the present invention.

FIG. 6 is a configuration diagram of a subscriber station communication device according to a fourth embodiment of the present invention.

FIG. 7 is a configuration diagram of an interference detection unit according to a fourth embodiment of the present invention.

FIG. 8 is a configuration diagram of a subscriber station communication apparatus according to a fifth embodiment of the present invention.

FIG. 9 is a diagram illustrating an example of a system configuration of a conventional subscriber wireless communication system.

FIG. 10 is a diagram showing an example of the configuration of a conventional subscriber station communication device.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 base station, 2 transmitting / receiving antenna, 3 base station communication device, 4 subscriber station, 5 transmitting / receiving antenna, 6 subscriber station communication device, 7 radio signal, 8 optical fiber relay transmission line, 9
Reception wave, 10 reception unit, 11 interface processing unit, 12 reception signal, 13 transmission unit, 14 transmission signal,
15 transmission wave, 16 terminal signal, 17 reception unit, 18 interference detection unit, 19 frequency-converted reception wave, 20 transmission unit,
21 interference information, 22 amplification section, 23 frequency conversion section, 2
4 distribution unit, 25 demodulation unit, 26 received wave after amplification, 27
Memory part, 28 adjacent leakage power information, 29 frequency spectrum, 30 power (dBm), 31 frequency (H
z), 32 frequency spectrum mask, 33 adjacent frequency Fad (Hz), 34 own frequency Fma (Hz),
35 relative power difference X (dBc), 36 interference detector, 3
7 band pass filter, 38 AGC amplifier, 39
Interference measurement unit, 40 interference reception wave, 41 AGC voltage, 4
2 interference detector, 43 diode detector, 44 detection voltage, 45 receiver, 46 frequency converter, 47 bandpass filter, 48 demodulator, 49 band-limited received wave, 50 demodulator, 51 AGC output wave.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (5)

(57) [Claims] 1. A base station comprising a transmitting / receiving antenna and a base station communication device and connected to a network such as a public network, and a plurality of subscriber stations comprising a transmitting / receiving antenna and a subscriber station communication device. In a subscriber wireless communication system for performing wireless communication between the base station and the subscriber station or the base station via the subscriber station, a frequency used by the subscriber station communication device is used. An interference detection unit capable of detecting the reception intensity of an adjacent frequency component is provided to the base station, and the interference information detected by the interference detection unit is transmitted to the base station directly or through a subscriber station. A subscriber wireless communication system, wherein 2. A subscriber radio system according to claim 1, further comprising a means for outputting the leakage power from the adjacent frequency corresponding to the reception intensity of adjacent frequency components to its own frequency. 3. An interference detector in the subscriber station communication device, comprising: a band-pass filter for passing only adjacent frequency components; and an AGC amplifier for detecting amplitude information of the band-pass filter. Subscriber wireless system as described. 4. An interference detecting section in the subscriber station communication apparatus, comprising: a band-pass filter for passing adjacent frequency components; and a detecting section including a diode capable of detecting amplitude information of the band-pass filter. Claim 1
Subscriber wireless system as described. 5. The apparatus according to claim 3 , wherein said bandpass filter transmits a frequency component adjacent to a frequency to be used to said AGC amplifier when said subscriber communication device is not communicating. Subscriber wireless system as described.