JP2596201B2 - Radio base station antenna device, centralized base station, mobile communication device, and reception condition measuring device for mobile communication - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a small-zone mobile communication system.

(Prior Art) In a mobile communication system such as an automobile telephone system,
The service area is divided into a plurality of zones, and a radio base station is arranged in each zone. By doing so, it becomes possible to repeatedly use the same frequency between radio base stations that do not cause interference and frequency resources can be used effectively. This method is called a small zone method.

As described on page 252 of the automobile telephone issued by the Institute of Electronics and Communication Engineers (supervised by Moriya Kuwahara), page 252, the radio base station of the automobile telephone system includes an antenna, an antenna sharing device, a transmitting and receiving device for communication and control, and a base station control. It is composed of devices and the like.

(Problems to be Solved by the Invention) In a mobile communication system, by dividing a service area into small zones, frequency utilization efficiency can be improved. In this case, a radio base station is installed on a streetlight or a telephone pole. Will be. However, the current wireless base station includes a transmission / reception device and a base station control device, and is an important issue when it is installed on a streetlight or a telephone pole. There has been a problem that realization of miniaturization and high reliability is not always easy.

In addition, the number of base stations provided for each zone
It will be more than 100 times. Therefore, in order to handle them in a distributed manner as before, there has been a problem that control of a wireless channel becomes very complicated.

For the purpose of the present invention, excellent low noise characteristics of optical linear transmission,
Utilizing low-distortion characteristics and wide-band characteristics, the transmission and reception radio signals of many dispersed base stations are handled intensively using optical transmission technology, realizing the miniaturization of radio base stations and the centralization of mobile telephone exchanges. It is an object of the present invention to provide a mobile communication system capable of performing supervised control.

(Means for Solving the Problems) The present invention provides an antenna for receiving a radio signal from a mobile terminal, and modulating the intensity of the optical signal with the radio signal received by the antenna to convert the radio signal into an optical signal. A radio base station antenna device comprising an electric / optical conversion circuit for conversion.

Or, an antenna for receiving a radio signal from a mobile terminal, an electric / optical conversion circuit for converting the radio signal into an optical signal by modulating the intensity of the optical signal with the radio signal received by the antenna, A wireless base station antenna device comprising: an optical / electrical conversion circuit that detects the intensity of an optical signal transmitted via a centralized base station, converts the intensity into a wireless signal, and outputs the wireless signal to the antenna.

Alternatively, the above-described wireless base station antenna device includes an automatic gain control circuit that amplifies a wireless signal received by the antenna to a constant output level and outputs the amplified signal to an electric / optical conversion circuit.

Alternatively, in the above-described radio base station antenna apparatus, a control signal of the automatic gain control circuit is superimposed on an output signal of the automatic gain control circuit and input to the electric / optical conversion circuit.

Alternatively, an optical / electrical conversion circuit for detecting the intensity of an optical signal sent from a wireless base station antenna device via an optical fiber and converting the intensity into an original wireless band signal, and a wireless band from the optical / electrical conversion circuit A demodulation circuit that receives the signal and demodulates the speech signal, a transmission circuit that converts the speech signal received from the exchange into a radio band signal, and modulates the intensity of the optical signal by the radio band signal from the transmission circuit. A centralized base station comprising: an electric / optical conversion circuit that converts the radio band signal into an optical signal and outputs the signal to the radio base station antenna device via the optical fiber.

Alternatively, there is provided a mobile communication device comprising the above-mentioned radio base station antenna device, the above-mentioned centralized base station, and an optical fiber connecting the radio base station antenna device and the centralized base station.

Alternatively, a base station control device for monitoring the output from each optical / electrical circuit or demodulation circuit of the centralized base station is provided, and the reception state measuring device for mobile communication is characterized by grasping the reception state of all mobile terminals. It is.

Alternatively, there is provided a switching device for selecting any one of the optical / potential circuit outputs of the centralized base station, and a measuring device for receiving the output of the switching device and measuring a reception state, and receiving a signal from the mobile terminal. Is measured based on the reception status of the base station currently in communication and the adjacent base station.

(Operation) In the present invention, a high-frequency signal received by a radio base station antenna is converted into an optical signal and transmitted to a mobile telephone exchange via a low-loss optical fiber. Therefore, the size of the wireless base station antenna device can be reduced, and the number of components can be reduced to improve reliability. However, there is a problem that it is not always easy to secure a carrier-to-noise ratio (C / N) required for optical transmission when the level of the high-frequency signal received by the wireless base station is low. Therefore, in the present invention, by providing an automatic gain control circuit, a radio signal received by an antenna is amplified to a constant output level to realize a sufficient C / N. The details will be described below.

Here, it is assumed that five carriers are used in each wireless zone. When multiplexing five carriers and modulating a semiconductor laser for optical transmission, the total modulation index is
If it exceeds 100%, large distortion occurs due to overmodulation, and sufficient characteristics cannot be obtained. Therefore, usually, the modulation index per channel is suppressed to 20% or less at the maximum. On the other hand, the C / N realized during optical transmission is about 80 dB at the maximum when the modulation index is 20%. Here, as the modulation index decreases, the C / N value realized decreases accordingly. Generally, in a mobile communication system, there is a difference of 60 dB or more in a signal level received by a radio base station antenna. Therefore, the carrier having the minimum signal level may not be able to satisfy the required C / N of 15 dB.

By the way, in a normal use state of a mobile communication system, a traffic peak rarely occurs, and a state in which the reception level of each carrier is high is extremely rare. Therefore, when the reception level of one carrier is low, the modulation index of the total of the semiconductor lasers is often much smaller than 100%. Here, the amplitude of the high-frequency signal component that modulates the semiconductor laser is detected, and its level is controlled so that the semiconductor laser is always modulated at a modulation index of almost 100%. The modulation is performed by the exponent, and sufficient C / N can be realized.

As described above, in the system in which the optical transmitter performs the automatic gain control, the C / N information or the like input to the control device accommodated in the mobile telephone exchange does not directly reflect the actual wireless communication state. If information on the control signal of the automatic gain control performed by each optical transmission unit is transmitted to the control device at the same time, the control device determines the reception status of the optical signal at the mobile telephone exchange and the wireless communication based on the control signal. It is possible to accurately grasp the communication state in.

In order to more accurately grasp the reception state of mobile communication, the following method is conceivable. When a mobile terminal is communicating at a predetermined frequency (f ₁ ) via a certain radio base station, it covers not only the communicating radio base station but also a zone adjacent to the zone covered by this radio base station. the radio base station of a frequency f ₁ received by size can be obtained if information is moving how mobile terminal if the monitor is a mobile terminal that also quickly captured when moving between zones it can.

In the mobile communication device according to the present invention, the signal received by the wireless base station antenna device is transmitted to the centralized base station as a wireless signal via an optical fiber. Therefore, if the signals from the radio base stations gathered at the centralized base station are switched and the same frequency signal is monitored, the reception state of one signal at different points can be known, and the position of one mobile terminal and the like can be determined. Learn more. If the frequency to be monitored is switched here, the reception status of different mobile terminals can be monitored. When the number of mobile terminals covered by one centralized base station is large, it is possible to grasp the reception state of all mobile terminals by increasing the number of monitoring devices.

(Example) Next, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, 1, 2, 3, 4, 5, and 6 indicate wireless zones. Reference numerals 10, 20, 30, 40, 50, and 60 denote base station antennas provided corresponding to the respective wireless zones. 100, 200,
Reference numerals 300, 400, 500, and 600 denote electrical / optical conversion circuits that convert wireless signals of each base station into optical signals. 1 ', 2', 3 ',
Reference numerals 4 ', 5' and 6 'denote transmission optical fibers for concentrating the signals of the respective base stations to the central station 9.

Reference numerals 1000, 2000, 3000, 4000, 5000, and 6000 are optical / electrical conversion circuits that return the optical radio signal to the original radio frequency signal.

A switching device 7 selects any one of these converters and supplies the output to the next measuring device 8.

In the present embodiment, the measuring device 8 has a synthesizer so that the radio frequency to be measured can be switched. Therefore, the mobile communication reception state measuring apparatus of the present embodiment could monitor the measurement states of different mobile terminals in a time-division manner. The measuring device 8 may be a receiving demodulator as it is, and the receiving state may be measured based on the quality of the demodulated signal, or only the power of the received signal may be observed. The broken line in FIG. 1 indicates a centralized base station.

Although only one fiber is drawn from each wireless zone in the embodiment shown in FIG. 1, when each base station handles a plurality of wireless channels, 1 'and 2' are correspondingly handled. Needless to say, there are a plurality of such fibers.

Furthermore, each wireless zone can be considered in correspondence with a fixed frequency repetition pattern (cell cluster). Also, by using a plurality of switching devices 7 and measuring devices 8, it is possible to increase the number of mobile terminals that can be monitored.

FIG. 2 is a diagram showing a second embodiment of the mobile communication device of the present invention. The mobile communication device includes a mobile terminal 11, a radio base station,
21 to 24, a centralized base station 91 and a mobile telephone exchange 51. Mobile terminal 11 and mobile telephone exchange 51
Is similar to a commonly used one, and its configuration is widely known to those skilled in the art. Further, in the embodiment of FIG. 2, the case where the number of the radio base station antenna devices is four will be described. However, it is also possible to add the radio base station antenna devices according to the conditions such as the range of the service area and the traffic. .

In the radio base station antenna device 21, the high frequency signal received by the antenna 20 is realized by a laser diode and its driver circuit via a transmission / reception splitter 203, a reception filter 205, and a reception amplifier 206. The signal is converted into an optical signal by 207, and the central
To the transmission / reception device. In the centralized base station 91, high-frequency signals are first reproduced by the optical / electrical conversion circuits 401 to 404, and demodulated by
The uplink communication signal is demodulated by 411 to 414 and transmitted to the mobile telephone exchange 51. Downlink call signals from the mobile telephone exchange 51 are converted to high-frequency signals by transmitters 415 to 418 in the centralized base station 91, and then converted to optical signals by electric / optical conversion circuits 405 to 408. The optical signal transmitted from the centralized base station 91 is input to an optical / electrical conversion circuit 201 realized by a photodiode and a front-end circuit of the radio base station antenna device 21, and transmitted via a transmission amplifier 202 and a transmission / reception splitter 203. ,antenna
Sent from 20. Other radio base station antenna equipment22
24 have the same configuration.

In the wireless antenna device 21 of the present embodiment, the reception amplifier 206 is constituted by a variable gain type amplifier, the output level of which is detected by the gain control circuit 208, and the output signal
By controlling the gain of 06, the level of the high-frequency signal input to the laser diode of the electric / optical conversion circuit 207 was kept constant, and the modulation index was always 95%. When the mobile communication system is actually operated, and when the gain control of the receiving amplifier 206 is not performed, the reception signal of the centralized base station 91 is not
The worst value of C / N was 15 dB, but by operating the gain control circuit 208 of the present embodiment, the modulation index for each carrier increased on average, and the worst value of C / N was improved to 25 dB. Was done.

FIG. 3 is a diagram for explaining a third embodiment of the present invention. The basic configuration of the mobile communication system of this embodiment is the second configuration.
This is the same as the embodiment. Wireless antenna device 21 of the present embodiment
In ~ 24, the output from the gain control circuit 208 is also sent to the electrical / optical conversion circuit 207, which is superimposed on the high frequency signal and transmitted to the centralized base station 91. The centralized base station 91 sends a signal from the gain control circuit 208 to the base station controller 61 together with information on the received signal. The base station controller 61 calculates the reception level of the signal from each mobile terminal 11 at the radio base station antenna device from the gain control information. This indicates a signal transmission state due to a distance between each mobile terminal and the radio base station antenna device or an obstacle. Depending on the system, the base station controller 61
Generates a control signal, thereby dynamically changing the transmission level of the radio base station antenna apparatus or the mobile terminal, thereby improving the signal transmission quality.

Actually, in the present embodiment, the reception level of the received signal from the same place changes every moment due to the operation of the gain control circuit 208 due to the operation of the gain control circuit 208. The base station controller 61 was able to accurately grasp the position and the like of each mobile terminal by judging the transmitted signals together. By transmitting a control signal based on this, the signal output of each mobile terminal 11 could be adjusted, and the dynamic range of the system could be substantially increased.

In the above embodiment, the case where the gain control circuit 208 is installed in the radio base station antenna devices 21 to 24 has been described. However, a similar gain control circuit is installed before the electrical / optical conversion circuit included in the centralized base station 91. It is also possible to do. Further, the radio antenna devices 21 to 24 and the centralized base station 91 are respectively connected by two optical fibers for transmission and reception, but the optical fibers can be shared by using an optical wavelength multiplexing technique. Further, in consideration of the size of the zone covered by each wireless antenna device, the traffic, the installation location of the wireless antenna device, etc., it is also possible to arrange both the one including the gain control circuit 208 and the one not including the gain control circuit 208. .

(Effects of the Invention) According to the present invention, the received signals are monitored at the base stations which are originally present separately, and this function can be collected at the centralized station by an optical fiber, and the mobile unit which moves between zones Can be efficiently captured.

Also, according to the present invention, by adding a gain control circuit to the radio base station antenna device, communication can be performed while maintaining a high C / N even when the radio reception signal level is low, and further in this state Since centralized monitoring of the entire area is possible and various line controls using the centralized monitoring can be performed, a high-quality mobile communication system can be provided.

[Brief description of the drawings]

FIG. 1, FIG. 2 and FIG. 3 are diagrams showing an embodiment of the mobile communication device of the present invention. 11 is a mobile terminal, 21 to 24 are radio base station antenna devices, 1, 2, 3, 4, 5, and 6 are radio zones 10, 20, 30, 40, 50, and 60 are base stations corresponding to each radio zone. Antennas, 100, 200, 300, 400, 500, 600 are electrical / optical conversion circuits, 1000, 2000, 3000, 4000, 5000, 6000 are optical / electrical conversion circuits, 7 is a switching device, 8 is a measuring instrument, 9, 91 is a centralized base station, 51 is a mobile telephone exchange, and 61 is a base station controller.

Continued on the front page (51) Int.Cl. ⁶ Identification number Reference number in the agency FI Technical display location H04Q 7/26 7/30 7/36

Claims (8)

(57) [Claims] An antenna for receiving a radio signal from a mobile terminal and an electric / optical conversion circuit for converting the radio signal into an optical signal by modulating the intensity of the optical signal by the radio signal received by the antenna. A radio base station antenna device. 2. An antenna for receiving a radio signal from a mobile terminal, an electric / optical conversion circuit for converting the radio signal into an optical signal by modulating the intensity of the optical signal with the radio signal received by the antenna, A radio base station antenna device comprising: an optical / electrical conversion circuit that detects the intensity of an optical signal transmitted from a switching center via a centralized base station, converts the intensity into a radio signal, and outputs the radio signal to the antenna. 3. The radio base according to claim 1, further comprising an automatic gain control circuit for amplifying a radio signal received by the antenna to a predetermined output level and outputting the amplified signal to an electric / optical conversion circuit. Station antenna device. 4. The radio base station antenna device according to claim 3, wherein a control signal of the automatic gain control circuit is superimposed on an output signal of the automatic gain control circuit and used as an input of the electric / optical conversion circuit. Wireless base station antenna device. 5. An optical / electrical conversion circuit for detecting the intensity of an optical signal transmitted from an antenna apparatus of a wireless base station via an optical fiber and converting the signal into an original wireless band signal, and A demodulation circuit that receives the radio band signal and demodulates the call signal, a transmission circuit that converts the call signal received from the exchange into a radio band signal, and modulates the intensity of the optical signal with the radio band signal from the transmission circuit. A centralized base station comprising: an electric / optical conversion circuit that converts the radio band signal into an optical signal by performing the operation and outputs the signal to the radio base station antenna device via the optical fiber. 6. A radio base station antenna device according to claim 2, 3, or 4, a centralized base station according to claim 5, and an optical fiber connecting said radio base station antenna device and said centralized base station. A mobile communication device comprising: 7. A mobile station comprising a base station control device for monitoring the output from each optical / electrical circuit or demodulation circuit of the centralized base station according to claim 5, and grasping the reception status of all mobile terminals. Communication reception condition measuring device. 8. A mobile terminal comprising: a switching device for selecting any one of the optical / potential circuit outputs of the centralized base station according to claim 5; and a measuring device for receiving the output of the switching device and measuring a reception state. Characterized in that it measures the reception status of a signal from the base station based on the reception status of the base station that is currently communicating and its adjacent base station.