KR20080023125A - Wireless relay apparatus and control method of wireless relay apparatus - Google Patents

Abstract

A wireless repeater and a method for controlling the same are provided to suppress what a transmitted signal acts as interfering noise for another adjacent wireless system under such circumstances that it is impossible to provide mobile communication services. A wireless repeater(3) comprises a downlink relay part(34), an uplink relay part(35), a service provider ID acquisition part(36) and a relay control part(37). The downlink relay part(34) relays a downlink signal transmitted from a base station. The uplink relay part(35) relays an uplink signal transmitted from a mobile station. The service provider ID acquisition part(36) extracts a service provider ID from the downlink signal. The relay control part(37) stops the relay processing of both the downlink relay part(34) and the uplink relay part(35) in case the extracted service provider ID is not matched with preset information.

Description

Wireless relay device and control method of wireless relay device {WIRELESS RELAY APPARATUS AND CONTROL METHOD OF WIRELESS RELAY APPARATUS}

The present invention relates to a wireless relay device used in a mobile communication system such as a DS-CDMA system.

In a mobile communication system, a radio relay device that relays and amplifies a radio signal between a base station (BS) and a mobile station (MS) provides an area where radio waves from a base station are hard to reach (so-called dead zone). Improve the communication environment. As a result, the covered area of the base station can be enlarged without newly constructing the base station.

Patent Literature 1 discloses a wireless relay device for reducing the operating power of an amplifier when there is no signal to be relayed for the purpose of reducing power consumption of the wireless relay device. Specifically, the wireless relay device disclosed in Patent Document 1 receives a radio signal transmitted from a radio communication station of a relay source, amplifies a received signal by an amplifier, and then relays the signal to a relay destination. It transmits to a wireless communication station. At this time, the wireless relay device disclosed in Patent Document 1 reduces the operating power of the amplifier for signal amplification when the signal power of the received signal before input to the amplifier is small compared to a predetermined threshold level. The operating power is zero.

That is, when it is determined that the radio relay apparatus disclosed in Patent Document 1 does not receive a relay target signal in the uplink direction transmitted from the mobile station toward the base station based on the signal level of the received signal, The amplifier for transmitting the relay target signal in the link direction toward the base station is stopped. Similarly, when the radio relay apparatus disclosed in Patent Document 1 determines that the relay target signal in the downlink direction transmitted from the base station toward the mobile station is not received, the radio relay device transmits the relay target signal in the downlink direction to the mobile station. Stops the amplifier for delivery.

[Patent Document 1] Japanese Patent Application Laid-Open No. 2000-82983 (JP 2000-82983A)

The radio relay apparatus disclosed in Patent Document 1 independently stops the relay process in the downlink direction from the base station to the mobile station and stops the relay process in the uplink direction from the mobile station to the base station. For this reason, in the conventional radio relay apparatus disclosed in Patent Document 1, even if it is impossible to provide a mobile communication service such as a case where a base station does not exist or a base station is broken, the mobile station transmits a message. The relay operation of the signal is continued. For this reason, there exists a possibility that the signal transmitted by a radio relay apparatus may become the interference wave of the other radio systems which exist in the vicinity of a radio relay apparatus.

In addition, the wireless relay device disclosed in Patent Document 1 determines the presence or absence of a relay target signal based on the signal level of the received signal. The inventors of the present application have found that the wireless relay device having such a configuration has problems described below. A telecommunications provider that provides mobile telecommunications services provides telecommunications services using radio frequency bands allocated on the basis of the permits or authorizations of governments or their organizations. For this reason, the radio relay apparatus usually does not cause a problem when the existence of the relay target signal based on the reception signal level is determined within the radio frequency band assigned to the communication operator operating the radio relay apparatus. However, a problem arises when the allocation of the radio frequency band to the telecommunications carrier is changed. That is, the radio relay apparatus should stop signal relaying in the radio frequency band when the user of the radio frequency band targeted for relaying is changed to a communication provider. However, if the signal level of the received signal is higher than or equal to a predetermined value, The relay operation is incorrectly judged to exist and the relay operation continues.

As described above, the conventional wireless relay apparatus cannot provide mobile communication services such as when the base station does not exist, when the base station is broken, or when the allocation of the wireless communication band to the communication provider is changed. In the following, there is a fear that the signal transmitted by the radio relay apparatus becomes a disturbance wave of another radio system existing around the radio relay apparatus.

The wireless relay device according to the first aspect of the present invention includes a downlink relay for relaying a downlink signal transmitted from a base station, an uplink relay for relaying an uplink signal transmitted from a mobile station, and the downlink signal. And a carrier identification information acquisition unit for acquiring carrier identification information for identifying a communication carrier and the downlink relay unit's relaying process and the uplink when the carrier identification information acquired from the downlink signal is not predetermined. It has a relay control part which stops the relay process of a relay part together.

As described above, the radio relay apparatus according to the first aspect of the present invention can stop signal relay in the downlink direction and the uplink direction together when the carrier identification information known from the base station is not predetermined. That is, it is determined by the operator identification information included in the notification information that the communication service provider using the radio frequency band that is the target of the relay processing is changed, and the signal relay in the downlink direction and the uplink direction is stopped according to the determination result. can do.

In addition, the wireless relay device according to the first aspect of the present invention also stops signal relay in the uplink direction in accordance with the carrier identification information included in the signal in the downlink direction. In other words, when the base station does not exist, when the service is suspended due to a failure of the base station, or when the mobile communication service is not available, such as when the allocation of the wireless communication band is changed, the relay of signals transmitted by the mobile station is impossible. The operation can be stopped. For this reason, the signal transmitted by the radio relay apparatus does not become a disturbance wave of other radio systems existing around the radio relay apparatus.

In the wireless relay apparatus according to the first aspect of the present invention described above, the relay control unit relays the downlink relay unit when a result of a combination of the operator identification information and predetermined combination information is inconsistent. You may stop the process and the relay process of the said uplink relay part together.

The radio relay apparatus according to the first aspect of the present invention described above may include a base station side receiving antenna, a base station side transmitting antenna, a mobile station side receiving antenna, and a mobile station side transmitting antenna. The downlink relay unit may further include a downlink amplifier for amplifying a received signal received by the base station side antenna and the mobile station side from the downlink amplifier according to a combination result of the operator identification information by the relay control unit. You may have a 1st signal cut-off part which cuts off the signal input to a transmitting antenna. The uplink relay unit may further include an uplink amplifier for amplifying a reception signal received by the mobile station side reception antenna and the base station from the uplink amplifier according to a combination result of the operator identification information by the relay control unit. You may have a 2nd signal blocking part which cuts off the signal input to a side transmission antenna. In addition, the base station side receiving antenna and the base station side transmitting antenna may be common. Further, the mobile station side receiving antenna and the mobile station side transmitting antenna may also be common.

Here, the first signal blocking unit is provided on a wiring between the downlink amplifier and the mobile station side transmitting antenna, and is a switch for electrically connecting or disconnecting between the downlink amplifier and the mobile station side transmitting antenna. It may be comprised. With this configuration, signal relaying can be stopped by controlling the electrical connection between the downlink amplifier and the mobile station side transmitting antenna, so that it is not essential to perform gain change control of the downlink amplifier. Therefore, the downlink amplifier can be a fixed gain amplifier whose gain is substantially constant, and a simple configuration in which gain change control is unnecessary can be adopted. The same applies to the uplink amplifier.

In addition, the above-mentioned wireless relay apparatus according to the first aspect of the present invention includes a first frequency converter for changing a carrier frequency of the downlink signal transmitted toward the mobile station, and the above-mentioned transmitted to the base station. It may be comprised with a 2nd frequency converter which changes the carrier frequency of an uplink signal. Accordingly, even when the radio frequency band used for signal transmission and reception of the base station is changed due to a change in the allocation of the radio communication band to the communication service provider, the mobile station can communicate using the radio frequency band before the change. For this reason, the signal which belongs to the radio frequency band after a frequency band change is sent to the mobile station side, and it can suppress that the signal after a frequency band change becomes the interference wave of the other radio systems which exist in the periphery of a radio relay apparatus.

The relay control unit is configured to be capable of holding a plurality of combination information, and the downlink relay unit may be configured when the operator identification information included in the downlink signal matches any one of the plurality of combination information. The relay process and the relay process of the uplink relay unit may be continued. As a result, for example, when the operator identification information obtained from the downlink signal matches any one of the plurality of combination information corresponding to the plurality of communication providers, the relay operation can be continuously performed.

In addition, the radio relay apparatus according to the first aspect of the present invention described above includes a first frequency converter for changing a carrier frequency of a downlink signal transmitted toward the mobile station, and a carrier of an uplink signal transmitted toward the base station. You may have a 2nd frequency converter which changes a frequency. The relay control unit may be configured to give an instruction to change the carrier frequency selected by the first and second frequency converters in accordance with the operator identification information obtained from the downlink signal. Thereby, the wireless section between the base station and the wireless relay device can be shared by relaying a plurality of signals having different operator identification information.

In addition, the wireless relay device according to the second aspect of the present invention inputs a commercial AC power supply to the downlink relay unit, the uplink relay unit, the operator identification information acquisition unit, and the relay control unit. You may further be provided with the power supply part which supplies. As a result, the wireless relay device can be easily installed in a house or an office of a mobile communication service user, which is difficult to install a current power supply device that is often used as a normal communication service provider equipment.

The method according to the second aspect of the present invention is a control method of a radio relay apparatus used in a mobile communication system. The method extracts carrier identification information for identifying a carrier from a downlink signal transmitted from a base station, and combines the carrier identification information extracted from the downlink signal with predetermined combination information to identify the carrier. When the information and the combination information do not match, processing for relaying the downlink signal and processing for relaying the uplink signal sent from the mobile station are stopped together.

By this method, signal relay in the downlink direction and the uplink direction can be stopped depending on whether or not the carrier identification information known from the base station and the previously held combination information are identical. That is, it is determined by the carrier identification information included in the notification information that the communication operator using the radio frequency band that is the target of the relay processing is changed, and the signal relay in the downlink direction and the uplink direction is stopped according to the determination result. Can be.

Further, according to the method according to the second aspect of the present invention, the signal relay on the uplink side is also stopped in accordance with the combination result of the carrier identification information included in the signal in the downlink direction. For this reason, in the situation where the mobile communication service cannot be provided, the signal transmitted by the radio relay apparatus does not become a disturbance wave of other radio systems in the vicinity of the radio relay apparatus.

A radio relay apparatus according to a third aspect of the present invention is a radio relay apparatus for relaying radio signals between a base station and a mobile station in a mobile communication system. The radio relay apparatus includes a base station side receiving antenna, a down link amplifier, a mobile station side transmitting antenna, a mobile station side receiving antenna, an up link amplifier, a base station side transmitting antenna, and relay control means. Here, the downlink amplifier amplifies the downlink received signal received by the base station side receiving antenna. The mobile station side transmitting antenna outputs the signal amplified by the downlink amplifier toward the mobile station at the relay destination. The uplink amplifier amplifies the uplink received signal received by the mobile station side receive antenna. The base station side transmitting antenna outputs the signal amplified by the uplink amplifier toward the base station at the relay destination. The relay control means combines an amplified relay of the downlink received signal and an amplified relay of the uplink received signal when a signal indicating the presence of the base station transmitted from the base station is not detected from the downlink received signal. Stop.

With such a configuration, when a signal indicating the presence of a base station transmitted from the base station (for example, a common pilot channel transmitted from the base station of the W-CDMA system) is not detected, only the downlink direction is used. In addition, the relay processing in the uplink direction can also be stopped. That is, according to the radio relay apparatus according to the third aspect, since the signal indicating the presence of the base station transmitted from the base station is not detected, it is determined that the service area of the base station is outside, and the bidirectional relay operation can be stopped. As a result, when the power of the radio relay apparatus is turned on in a place where the signal from the base station does not arrive, or when the radio relay apparatus is installed in advance of the base station, the bidirectional relay operation of the radio relay apparatus can be stopped.

In addition, since the radio relay apparatus according to the third aspect stops the relay operation in accordance with the presence or absence of a signal indicating the presence of a base station, it transmits from a base station when any signal such as a jamming wave exists in the frequency band of the downlink signal. It is possible to prevent the radio relay from malfunctioning by misrecognizing that a signal has been detected.

According to the present invention, when a base station does not exist, when a base station fails, or when a mobile communication service is not provided, such as when the allocation of a wireless communication band is changed, the signal transmitted by the radio relay apparatus is wireless. It is possible to suppress the interference of other radio systems in the vicinity of the relay device.

(The best form to carry out invention)

EMBODIMENT OF THE INVENTION Hereinafter, the specific embodiment which applied this invention is described in detail, referring drawings. In each figure, the same code | symbol is attached | subjected to the same element, and overlapping description is abbreviate | omitted as needed for clarity of description.

(Embodiment 1 of the invention)

The wireless relay device 1 according to the present embodiment is a device for performing signal relay between a base station BS and a mobile station MS in a W-CDMA wireless communication system. The configuration of the wireless relay device 1 is shown in FIG. In the case of performing the downlink signal relay from the base station to the mobile station, the radio relay device 1 receives the transmission signal of the base station by the base station side antenna 10 and amplifies the received signal by the amplifier 14. The transmission is then transmitted from the mobile station side antenna 11. On the other hand, in the case of performing an uplink signal relay from the mobile station to the base station, the wireless relay device 1 receives the transmission signal of the mobile station by the mobile station side antenna 11, and receives the received signal by the amplifier 15. After amplification, transmission is performed from the base station side antenna 10. Hereinafter, each component shown in FIG. 1 is demonstrated.

In Fig. 1, the base station side antenna 10 is an antenna for receiving a signal transmitted from a base station and transmitting a signal to the base station. The mobile station side antenna 11 is an antenna that transmits a signal to the mobile station and receives a signal transmitted from the mobile station.

The duplexer 12 is provided for sharing the base station side antenna 10 for transmission and reception. Specifically, a signal in the downlink frequency band (for example, 2.1 GHz band in W-CDMA) received by the base station side antenna 10 is distributed to the amplifier 14. The duplexer 12 also outputs a signal in the uplink frequency band (for example, 1.9 GHz band in W-CDMA) input from the amplifier 15 to the base station side antenna 10.

The duplexer 13 is installed to share the mobile station antenna 11 for transmission and reception. Specifically, the uplink frequency band signal received by the mobile station antenna 11 is distributed to the amplifier 15. The duplexer 13 also outputs a signal of the downlink frequency band input from the amplifier 14 through the switch 16 to the mobile station antenna 11.

The amplifier 14 is an amplifier that amplifies power in the downlink frequency band, and amplifies and outputs signal power of a signal input from the duplexer 12. The amplifier 15 is an amplifier that amplifies the power in the uplink frequency band, and amplifies and outputs the signal power of the signal input from the duplexer 13.

The switch 16 is provided on the wiring for connecting between the amplifier 14 and the duplexer 13. The switch 16 is a circuit for electrically connecting or disconnecting between the amplifier 14 and the mobile station side antenna 11 in accordance with the switch control signal S1 output from the signal detection unit 17 described later. That is, the switch 16 is a circuit which controls the electrical connection state between the amplifier 14 and the mobile station antenna 11.

When the signal detection unit 17 determines whether there is a signal to be relayed to the mobile station, that is, whether there is a downlink signal transmitted from the base station using the output signal of the amplifier 14, and there is no downlink signal to be relayed The switch 16 is opened so that the output signal of the amplifier 14 is not transmitted from the mobile station side antenna 11. In addition, control of the switch 16 by the signal detection part 17 is performed by the switch control signal S1.

One convenient configuration for determining the presence or absence of a downlink signal by the output signal of the amplifier 14 is to use the amplifier 14 as a fixed gain amplifier whose gain is substantially constant, thereby reducing the signal power of the output signal of the amplifier 14. It is a structure compared with a predetermined threshold level. Specifically, when the output signal power of the amplifier 14 is larger than the predetermined threshold, the signal detector 17 closes the switch 16 to output the output signal of the amplifier 14 to the duplexer 13 and the mobile station side antenna. Output to (11). On the other hand, when the output signal power of the amplifier 14 is smaller than the predetermined threshold value, the signal detector 17 disconnects the connection between the amplifier 14 and the duplexer 13 by opening the switch 16.

However, in the above-described simple configuration, there is a problem in that the determination accuracy of the presence or absence of the downlink signal to be relayed is low. For example, in the case where a jamming wave exists in the frequency band of the downlink, the jamming wave is amplified so that the output signal power of the amplifier 14 exceeds the threshold level, even though there is no downlink signal to be relayed. The relay process may be executed and discarded. In order to prevent such a malfunction, it is preferable to perform the despreading process corresponding to the signal transmitted from the base station to the output signal of the amplifier 14, and then determine the presence or absence of the downlink signal using the despread signal. Specifically, the despreading process for demodulating the pilot signal transmitted from the base station at all times may be performed.

2 shows an example of the configuration of a signal detector 14 for determining the presence or absence of a pilot signal transmitted from a base station. In FIG. 2, the mixer 140, the local oscillator 141, and the low pass filter (LPF) 142 convert the RF (Radio Frequency) signal input from the amplifier 14 into an IF ( It is installed for down converting to Intermediate Frequency signal. In other words, the mixer 140 multiplies the input RF signal with the signal generated by the local oscillator 141. The LPF 142 then outputs the band after selecting the output signal of the mixer 140.

The CPICH despreader 143 inputs an IF signal from the LPF 142 and executes a despreading process corresponding to a common pilot channel (CPICH). The CPICH is a pilot signal transmitted from the base station of the W-CDMA system. For example, an analog matched filter can be used as the CPICH despreader 143. Alternatively, when the IF signal after A / D conversion is input, a digital matched filter can be used as the CPICH despreader 143.

The spreading code generator 144 despreads the CPICH by spreading the spreading code (specifically, the spreading code common to the channelization code and the scramble code) used in the spreading process of the CPICH in the base station. It supplies to the part 143.

The signal level determining unit 145 compares the signal power of the signal narrowed by the despreading process in the CPICH despreading unit 143 with a predetermined threshold, and according to the comparison result, the switch control signal S1. Outputs More specifically, the signal level determining unit 145 closes the switch 16 when the signal power after the despreading process is larger than the predetermined threshold, and opens the switch 16 when the signal power is smaller than the predetermined threshold. The switch control signal S1 is output.

In addition, it is preferable to set the threshold applied to the signal level determining unit 145 to a power level in consideration of the processing gain due to despreading of the CPICH. In other words, by despreading using a spread code corresponding to the CPICH, the signal power of the interference waves other than the CPICH is reduced to one-spread spread factor on average. For this reason, by determining the presence or absence of the downlink signal to be relayed by the presence or absence of CPICH after despreading, it is possible to suppress the misjudgment in the case where a disturbance wave exists in the downlink frequency band.

As described above, the wireless relay device 1 according to the present embodiment determines the presence or absence of a downlink signal to be relayed using the signal amplified by the amplifier 14. Thereby, even when the signal power of the received signal which the radio relay apparatus 1 receives from a base station is very small, the signal power required for determination of the presence or absence of a downlink signal can be obtained. For this reason, compared with the structure which determines the presence or absence of the signal which should be relayed by the signal level of the received signal before amplification, the determination precision of the presence or absence of the signal which should be relayed can be improved.

In addition, the wireless relay device 1 is configured to block the connection between the amplifier 14 and the mobile station antenna 11 when there is no signal to be relayed. For this reason, the signal relay in the downlink direction can be stopped without stopping the operation of the amplifier 14 of the radio relay 1. That is, since the wireless relay device 1 does not require gain change control of the amplifier 14, it is possible to reduce the cost by adopting a simple configuration using an amplifier having a constant gain. Also, as in the radio relay device 1 disclosed in Patent Literature 1, the configuration of changing the gain of the amplifier in accordance with the signal level of the received signal adopts the operation of the amplifier when the signal level variation of the received signal frequently occurs. It is concerned that the instability and the gain change of the amplifier cannot sufficiently follow the signal level fluctuation of the received signal, but this problem can be solved by adopting a simple configuration using an amplifier with a constant gain.

(Other embodiments)

The above-mentioned wireless relay device 1 is a circuit for controlling the electrical connection state between the amplifier 14 and the mobile station antenna 11, and uses a switch 16 that operates in accordance with the control signal S1. have. However, the means for controlling the electrical connection state between the amplifier 14 and the mobile station side antenna 11 is not limited to the switch 16. For example, a variable attenuator may be provided on the wiring between the amplifier 14 and the mobile station side antenna 11. In such a configuration, the attenuation amount of the variable attenuator may be increased as the CPICH is not detected, and the attenuation amount of the variable attenuator may be reduced as the CPICH is detected.

The amplifier 14 included in the above-mentioned wireless relay device 1 has been described as a fixed gain amplifier whose gain is substantially constant. However, the amplifier 14 does not have to have a constant gain. For example, you may perform gain control, what is called AGC (automatic gain control) which makes the output signal power of the amplifier 14 constant, using the amplifier 14 as a variable gain amplifier.

The above-mentioned wireless relay device 1 is configured to stop only signal relay in the downlink direction depending on the presence or absence of a signal to be relayed, but also stops signal relay in the uplink direction in accordance with the presence or absence of a signal to be relayed. You may make it.

3 shows a wireless relay device 2 configured to stop signal relays in the downlink direction and the uplink direction together depending on whether there is a downlink signal to be relayed, specifically, whether a pilot signal transmitted from a base station is detected. .

The switch 26 of FIG. 3 is provided on the wiring for connecting between the amplifier 15 and the duplexer 12, and in accordance with the switch control signal S1 output from the signal detection unit 17. FIG. A circuit for electrically connecting or disconnecting between the amplifier 15 and the base station side antenna 10.

Although the above-mentioned wireless relay device 1 has been described as being used in a W-CDMA wireless communication system, the present invention is also applicable to other DS-CDMA systems such as the cdma 2000 system. In addition, the present invention is not limited to the DS-CDMA system, but can be applied to other direct diffusion wireless communication systems or other wireless communication systems.

(Embodiment 2 of the invention)

The wireless relay device 3 according to the present embodiment is a device for performing signal relay between a base station BS and a mobile station MS in a W-CDMA wireless communication system. The configuration of the wireless relay device 3 is shown in FIG. The wireless relay device 3 receives the transmission signal of the base station by the base station side antenna 10, amplifies the received signal by the amplifier 341 included in the downlink relay unit 34, and then amplifies the down signal. The link signal is transmitted from the mobile station side antenna 11. Accordingly, signal relay in the downlink direction from the base station to the mobile station is executed.

In addition, the wireless relay device 3 receives the transmission signal of the mobile station by the mobile station antenna 11, amplifies the received signal by the amplifier 351 included in the uplink relay unit 35, and amplifies the signal. The later uplink signal is transmitted from the base station side antenna 10. As a result, signal relay in the uplink direction from the mobile station toward the base station is performed. Hereinafter, each component shown in FIG. 4 is demonstrated.

In Fig. 4, the base station side antenna 10, the mobile station side antenna 11, the duplexer 12, and the duplexer 13 are the same as those in the first embodiment of the above description.

The downlink relay 34 has an amplifier 341 and a switch 342. The amplifier 341 is an amplifier that amplifies power in the downlink frequency band, and amplifies and outputs signal power of a signal output from the duplexer 12.

The switch 342 is provided on the wiring connecting the amplifier 341 and the duplexer 13. The switch 342 is a circuit for electrically connecting or disconnecting between the amplifier 341 and the mobile station side antenna 11 in accordance with the control signal S1 output from the relay control section 37 to be described later. That is, the switch 342 is a circuit which cuts off the signal input from the amplifier 341 to the mobile station antenna 11 in order to stop the downlink relay process by the downlink relay unit 34.

The uplink relay unit 35 has an amplifier 351 and a switch 352. The amplifier 351 is an amplifier that amplifies the power in the uplink frequency band, and amplifies and outputs the signal power of the signal input from the duplexer 13.

The switch 352 is provided on the wiring connecting the amplifier 351 and the duplexer 12. The switch 352 is a circuit for electrically connecting or disconnecting between the amplifier 351 and the base station side antenna 10 in accordance with the control signal S1 output from the relay control section 37 to be described later. That is, the switch 352 is a circuit which cuts off the signal input from the amplifier 351 to the base station side antenna 10 in order to stop the uplink relay process by the uplink relay part 35.

The amplifiers 341 and 351 may be variable gain amplifiers having an AGC (Automatic Gain Control) circuit that controls the signal power after amplification to be constant, or may be a fixed gain amplifier having a substantially constant gain.

The operator identification information acquisition unit 36 acquires the operator identification information from the downlink signal transmitted from the base station. Here, the operator identification information is information for identifying a communication company that provides a mobile communication service. That is, the carrier identification information transmitted from the base station is a signal indicating the existence of the base station and is also a signal indicating the communication provider that is the source of the signal.

For example, in the case of the W-CDMA system, notification information including a PLMNid (Public Land Mobile Network Identifier) is transmitted from the base station, as shown in FIG. In addition, the PLMNid includes a country code (MCC) and a mobile network code (MNC). For this reason, PLMNid can be used as company identification information. The notification information including the PLMNid is included in a broadcast channel (BCH) which is a common transport channel in the downlink direction. In addition, the BCH is transmitted from the base station using a primary common control physical channel (P-CCPCH), which is a common physical channel in the downlink direction.

The relay control unit 37 combines the operator identification information acquired by the operator identification information acquisition unit 36 with the combination information. Here, the combination information is information for verifying whether or not the company identification information acquired by the company identification information acquisition unit 36 indicates a company to be subjected to signal relay. Specifically, what is necessary is just to make company identification information corresponding to the business operator which should be the target of signal relaying as information for combination. As an example, in the case of the W-CDMA system, the combination information may be a PLMNid corresponding to a provider to be subjected to signal relay. Moreover, the relay control part 37 controls the operation of the switches 342 and 352 by the control signal S1 according to the combination result of the operator identification information and the combination information. Specifically, when the operator identification information and the combination information coincide, the relay control unit 37 closes the switches 342 and 352 to enable signal relay in the downlink direction and the uplink direction. On the other hand, when there is a discrepancy between the operator identification information and the combination information, the relay control section 37 opens the switches 342 and 352 to stop the signal relay in the downlink direction and the uplink direction.

The power supply unit 38 inputs commercial AC power supplies such as AC 100V and AC 240V, performs voltage conversion, rectification, and smoothing, and supplies operating power to the respective parts of the wireless relay device 3.

Subsequently, a specific structural example of the company identification information acquisition unit 36 will be described. 5 shows an example of the configuration of the company identification information acquisition unit 36. 5, the IF converter 360 down converts the input RF (Radio Frequency) signal into an IF (Intermediate Frequency) signal. Specifically, the IF converter 360 includes a mixer (not shown), a local oscillator (not shown), a low pass filter (not shown), and an A / D converter (not shown). The IF converter 360 multiplies the input RF signal with the signal generated by the local oscillator in the mixer, band-selects the output signal of the mixer in the low pass filter, and A / A the signal after passing the low pass filter. The D converter samples and outputs the digital signal after sampling.

The matched filter 361 executes the despreading process by a correlation operation between the spread code replica corresponding to the primary common control physical channel P-CCPCH and the input signal. The spreading code generator 362 outputs a spreading code common to the spreading code (specifically, a channelization code and a scramble code) used for spreading processing of the P-CCPCH at the base station to the matched filter 361. do.

The matched filter 363 executes the despreading process by a correlation operation between a spread code replica corresponding to a common pilot channel (CPICH) and an input signal. The spread code generator 364 outputs a spread code common to the spread code used for spread processing of the CPICH at the base station to the matched filter 363.

The channel estimator 365 estimates the channel using the signal output from the matched filter 363 to generate a delay profile corresponding to the multipath with the base station. . The RAKE combining unit 366 performs RAKE combining using the delay profile measured by the channel estimating unit 365. The BCH decoding unit 367 de-interleaves and decodes the data sequence after RAKE synthesis to decode the BCH. The PLMNid extracting unit 367 extracts PLMNid which is operator identification information from the decoded BCH.

As described above, the wireless relay device 3 according to the present embodiment has the downlink direction and the uplink direction when the carrier identification information included in the downlink signal does not match with the combination information held in advance. Stop signal relaying. That is, it is possible to judge that the carrier using the radio frequency band targeted for the relay processing has been changed by the carrier identification information known from the base station, and the signal relay in the downlink direction and the uplink direction is determined according to the determination result. You can stop.

In addition, the wireless relay device 3 according to the present embodiment stops not only the downlink direction but also the signal relay in the uplink direction in accordance with the combination result of the carrier identification information included in the downlink signal. That is, when the base station does not exist, when the base station fails, or when the mobile communication service cannot be provided, such as when the allocation of the wireless communication band has been changed, the radio relay device 3 may be configured to have a mobile station. The relay operation of the signal to be sent can be stopped. For this reason, the signal which the radio relay device 3 transmits does not become the interference wave of the other radio systems which exist in the vicinity of the radio relay device 3.

In addition, since the wireless relay device 3 according to the present embodiment is enabled to operate by electric power supplied from a commercial AC power supply, it is difficult to install a DC power supply device which is often used in ordinary communication service equipment. It can be easily installed in a house or office of a mobile communication service user.

(Other embodiments)

The above-mentioned wireless relay device 3 includes a first frequency converter for changing a carrier frequency of a downlink signal transmitted toward a mobile station, and a second frequency converter for changing a carrier frequency of an uplink signal transmitted toward a base station. It may be configured with. 7 shows a modification of the radio relay apparatus 3. The radio relay apparatus 4 shown in FIG. 7 includes a frequency converter 443 for changing the carrier frequency of the downlink signal and a frequency converter 453 for changing the carrier frequency of the uplink signal. With such a configuration, even when the radio frequency band transmitted and received by the base station is changed due to a change in the allocation of the radio communication band to the communication service provider, the mobile station can communicate by the radio frequency band before the change. For this reason, the signal which belongs to the radio frequency band after a change is sent to the mobile station side, and it can suppress that the signal after a band change becomes the interference wave of the other radio systems which exist in the periphery of a radio relay apparatus.

In addition, in the above-mentioned wireless relay device 3, the relay control unit 37 holds a plurality of combination information, and the operator identification information included in the received downlink signal is any one of the plurality of combination information. In the case of coinciding with, signal relaying may be performed.

In addition, the above-mentioned wireless relay device 3 maintains table data indicating a correspondence relationship between the carrier identification information and the carrier frequency as shown in FIG. 8, and transmits and transmits downlink signals. May be configured to change the carrier frequency applied to reception of the signal according to the carrier identification information. A modification of the radio relay device 3 is shown in FIG. The radio relay apparatus 5 shown in FIG. 9 holds table data as shown in FIG. 8, and determines the change of the carrier frequency according to the received carrier identification information PLMNid. The relay control unit 57 included in the radio relay 5 outputs a control signal S2 for instructing the change of the carrier frequency. The frequency converters 343 and 353 of the radio relay 5 change the carrier frequency in accordance with the control signal S2.

In addition, although the above-mentioned wireless relay device 3 uses PLMNid included in the notification information from the base station as the operator identification information, such a configuration is an example. That is, the carrier identification information may be other information that can identify the carrier, not just the PLMNid.

The radio relay apparatus 3 described above is a circuit for blocking signal input from the amplifier 341 to the mobile station antenna 11 and a circuit for blocking signal input from the amplifier 351 to the base station antenna 10. The switches 342 and 352 are used. However, the configuration for blocking the signal input is not limited to the switches 342 and 352 for controlling the electrical connection state. For example, a variable attenuator capable of changing the attenuation amount may be provided on the wiring between the amplifier 341 and the mobile station side antenna 11 and on the wiring between the amplifier 351 and the base station side antenna 10. In such a configuration, it is sufficient to reduce the attenuation amount of the variable attenuator when the combination result of the operator identification information is inconsistent. In addition, when adopting a configuration in which the acquisition of the operator identification information is performed at the front end of the amplifier 341, the gain of the amplifier 341 may be reduced when the combination result of the operator identification information is inconsistent.

In addition, although the radio relay apparatus 3 mentioned above shares the base station side antenna 10 and the mobile station side antenna 11 by transmission and reception, you may provide a transmission antenna and a reception antenna independently.

In addition, although the wireless relay device 3 mentioned above is comprised so that it may operate by inputting commercial AC power supply, you may change such a structure and operate so that it may operate by the electric power supplied from external DC power supply devices, such as a current stabilization power supply. .

In addition, although the radio relay apparatus 3 mentioned above was used as being used in the W-CDMA system | wireless communication system, this invention is applicable also to other DS-CDMA systems, such as a cdma2000 system. In addition, the present invention is not limited to the DS-CDMA system, but can be applied to other direct diffusion wireless communication systems or other wireless communication systems.

In addition, the above-mentioned wireless relay device 3 can be used not only for directly relaying signals transmitted from the base station and the mobile station, but also for the purpose of relaying signals transmitted from these through other wireless relay devices.

In addition, this invention is not limited only to embodiment mentioned above, Of course, various changes are possible in the range which does not deviate from the summary of this invention mentioned above.

1 is a configuration diagram of a wireless relay apparatus according to Embodiment 1 of the present invention.

2 is a block diagram of a signal detection unit included in the radio relay apparatus according to the first embodiment of the present invention.

3 is a configuration diagram showing a modification of the radio relay apparatus according to the first embodiment of the present invention.

4 is a configuration diagram of a radio relay apparatus according to Embodiment 2 of the present invention.

5 is a configuration diagram of a company identification information acquisition unit of the radio relay apparatus according to the second embodiment of the present invention.

6 is a diagram illustrating an example of notification information sent from a base station.

7 is a configuration diagram of a wireless relay device according to another embodiment of the present invention.

Fig. 8 is a diagram showing an example of a table showing a correspondence relationship between the carrier identification information and the mobile station carrier frequency.

9 is a configuration diagram of a wireless relay device according to another embodiment of the present invention.

(Explanation of symbols for the main parts of the drawing)

1, 2, 3, 4, 5: radio repeater

10: base station side antenna

11: mobile station antenna

12, 13: duplexer

14, 15: amplifier

16, 26: switch

17: signal detector

140: mixer

141 local oscillator

142: low pass filter (LPF)

143 CPICH despreading unit

144: spread code generator

145: signal level determination unit

34: downlink relay

341 amplifier

342: switch

35: uplink relay

351: Amplifier

352: switch

36: business identification information acquisition unit

37, 57: relay control unit

38: power supply

360: IF converter

361: matched filter

362: spreading code generator

363: matched filter

364: spreading code generator

365: transmission path estimator

366: RAKE synthesis section

367: BCH decoder

368: PLMNid extraction unit

443, 543: frequency converter

453, 553: frequency converter

Claims (15)

A downlink relay unit for relaying downlink signals transmitted from the base station, An uplink relay unit for relaying uplink signals transmitted from the mobile station, A carrier identification information acquisition unit for acquiring carrier identification information for identifying a carrier from the downlink signal; A relay control unit which stops the relaying process of the downlink relay unit and the relaying process of the uplink relay unit together when the carrier identification information obtained from the downlink signal is not predetermined; Wireless relay device comprising a. The method of claim 1, The relay control unit stops the relay process of the downlink relay unit and the relay process of the uplink relay unit together when a result of combining the operator identification information and predetermined combination information is inconsistent. . The method of claim 2, A base station receiving antenna, A base station side transmit antenna, A mobile station receiving antenna, Further comprising a mobile station side transmit antenna, The downlink relay unit, A downlink amplifier for amplifying a received signal received by the base station side receiving antenna; A first signal blocking unit for blocking signal input from the downlink amplifier to the mobile station side transmitting antenna in accordance with a result of the combination of the operator identification information by the relay control unit; The uplink relay unit, An uplink amplifier for amplifying a received signal received by the mobile station side receiving antenna; And a second signal blocking unit for blocking a signal input from the uplink amplifier to the base station side transmitting antenna in accordance with a combination result of the operator identification information by the relay control unit. The method of claim 3, The first signal cut-off unit is a switch circuit provided on a wiring between the downlink amplifier and the mobile station side transmitting antenna, the switch circuit electrically connecting or disconnecting between the downlink amplifier and the mobile station side transmitting antenna. Relay device. The method of claim 1, A first frequency converter for changing a carrier frequency of the downlink signal transmitted toward the mobile station; And a second frequency converter configured to change a carrier frequency of the uplink signal transmitted toward the base station. The method of claim 2, The relay control unit is configured to be capable of holding a plurality of combination information, and relay processing of the downlink relay unit when the operator identification information included in the downlink signal matches any one of the plurality of combination information. And a relay apparatus for continuing the relay processing of the uplink relay unit. The method of claim 6, A first frequency converter for changing a carrier frequency of the downlink signal transmitted toward the mobile station; And a second frequency converter for changing a carrier frequency of an uplink signal transmitted toward the base station, And the relay control unit instructs the carrier frequency selected by the first and second frequency converters to be changed by the operator identification information. The method according to any one of claims 1 to 7, And a power supply unit configured to input a commercial AC power source and supply operating power to the downlink relay unit, the uplink relay unit, the operator identification information acquisition unit, and the relay control unit. A control method of a wireless relay device used in a mobile communication system, From the downlink signal transmitted from the base station, carrier identification information for identifying a carrier is extracted, Combining the carrier identification information extracted from the downlink signal with predetermined combination information, And a process of relaying the downlink signal and a process of relaying an uplink signal transmitted from a mobile station when the service provider identification information and the combination information are inconsistent. The method of claim 9, When combining the operator identification information with the combination information, in combination with a plurality of combination information corresponding to a plurality of carriers, And if the service provider identification information does not match any of the plurality of combination information, the relaying process of the downlink signal and the uplink signal is stopped. A wireless relay apparatus for relaying a radio signal between a base station and a mobile station in a mobile communication system, A base station receiving antenna, A downlink amplifier for amplifying a downlink received signal received by the base station receiving antenna; A mobile station side transmitting antenna for outputting the signal amplified by the downlink amplifier toward the mobile station at a relay destination; A mobile station receiving antenna, An uplink amplifier for amplifying an uplink received signal received by the mobile station side receiving antenna; A base station side transmit antenna for outputting a signal amplified by the uplink amplifier toward the base station at a relay destination; Relay control means for stopping the amplification relaying of the downlink receiving signal and the amplification relaying of the uplink receiving signal together when a signal indicating the presence of the base station transmitted from the base station is not detected from the downlink receiving signal; Wireless relay device provided. The method of claim 11, And the base station side reception antenna and the base station side transmission antenna are shared, and the mobile station side reception antenna and the mobile station side transmission antenna are shared. The method according to claim 11 or 12, wherein And a signal indicating the presence of the base station is a pilot channel spread-modulated by a direct spreading method. The method of claim 13, And a detecting section for executing the despreading process corresponding to the pilot channel on the output signal of the downlink amplifying section, When the signal power after the despreading process by the detection unit falls below a predetermined threshold, the relay control means inputs the signal from the downlink amplifier to the mobile station side transmitting antenna and from the uplink amplifier. Stop signal input to the base station side transmitting antenna, And the threshold value is set to a value in consideration of the processing gain by the despreading process of the pilot channel. A control method of a radio relay apparatus for relaying radio signals between a base station and a mobile station in a mobile communication system, Detects whether or not a signal indicating the presence of the base station transmitted from the base station is included in a downlink received signal received by a base station side receiving antenna, When a signal indicating the presence of the base station is not detected from the downlink reception signal, the processing for relaying the downlink reception signal and the processing for relaying the uplink reception signal received by the mobile station side receiving antenna are stopped together. A control method of a wireless relay device to make.

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