JP2009010781A - Wireless relay apparatus, and control method for wireless relay apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless relay apparatus in which bit errors caused by wireless relay are reduced and communication quality is prevented from deteriorating, when a high-speed information channel is deleted in the wireless relay apparatus, and to provide a control method for the wireless relay apparatus. <P>SOLUTION: In the wireless relay apparatus, an uplink reception signal is temporarily decoded, its bit error is corrected by error correction processing, and the reception signal is then re-encoded and relayed so that uplink bit error is prevented from being contained in a downlink. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a radio relay apparatus and a control method for the radio relay apparatus, and more particularly to a radio relay unit that reduces deterioration in communication quality associated with relay processing.

  In land mobile radio (LMR) for fire fighting, administrative radio and other commercial radios, in addition to in-vehicle, portable, and shoulder type portable types, there are various types such as fixed and semi-fixed types. However, in recent years, the frequency band per carrier channel is being narrowed and digitized. In digitalization, frequency division multiplexing (FSK) using frequency modulation keying (FMSK) is used because of coexistence with existing analog radios, diversion of existing equipment, and ease of control. In many cases, Frequency Division Multiple Access (FDMA) is employed.

  In a digital wireless communication system, data to be transmitted is transmitted and received in units of frames. On the transmitter side, a sync signal having a specific signal arrangement pattern at a predetermined position of each frame (frame sync word: “FSW”) (Abbreviated) is transmitted, and the receiver establishes synchronization by detecting the frame synchronization word in the detection output signal. Also, when transmitting digital signals, it is possible to detect the presence or absence of bit errors due to noise mixing during transmission by adding an error correction function, not limited to wireless communication, and correct (correct) them depending on the method. Is possible. The frame configuration, symbol timing, and error correction method in such a digital wireless system are configured based on a predetermined communication protocol.

In mobile radio communication systems, there are radio wave insensitive zones where radio waves do not reach everywhere in mountainous areas and areas where high-rise buildings in the city are lined up. In particular, since the use of a high frequency band in the GHz band has been advanced in recent years, the need for a wireless relay means has further increased.
In this case, as in MCA (multi-access wireless system), communication is not performed directly between mobile communication terminals, and all communication is performed via a control station (base station), or a mobile phone system is used. The base station apparatus in the cellular mobile radio system is described as being included in the radio relay apparatus, and the mobile communication terminal includes terminals in these systems.

  FIG. 5 is a system schematic diagram of a general digital radio system. Reference numerals 101 and 102 denote mobile communication terminals A and B, which transmit frame signals encoded according to a predetermined protocol including error correction. Or a function capable of receiving. Reference numeral 103 denotes a wireless relay device for relaying communication between the plurality of mobile communication terminals. The wireless relay device 103 receives a signal transmitted from the mobile communication terminals 101 and 102, and sends the received signal to the mobile communication terminal. On the other hand, a transmission apparatus including a function of converting to a required frequency or another channel and retransmitting is provided. In general, a communication line from a mobile communication terminal to a radio relay apparatus is often called an uplink (Up link), and a reverse line is called a downlink (Do link).

FIG. 6 is a frame configuration diagram showing an example of signals transmitted and received in such a mobile radio system. FIG. 6A shows an example of a frame signal transmitted from a mobile communication terminal. The FSW arranged at the head of the frame is the frame synchronization word (FSW), LI is various link information, and SCH is attached to each frame. The low-speed information channel VCH on which the low-speed communication data is arranged is a voice channel, and in this example, four voice channels VCH1 to VCH4 are arranged in one frame.
Also, as shown in FIG. 6 (b), when transmission of voice signals is interrupted as necessary and communication data is transmitted at high speed, it is transmitted as one high-speed information channel FCH instead of two voice channels. It has a function. In the example shown in the figure, all four voice channels are replaced with high-speed information channels, but only one of them may be used.

The radio wave transmitted from the mobile communication terminal 101 in this manner arrives at the radio relay apparatus 103 via the uplink, is converted to a required frequency (or channel), and is directed to the mobile communication terminal 102 via the downlink. Will be retransmitted. In the wireless relay device, the contents of the voice channel of the frame are basically not changed, but the data of the information channel may be changed or deleted / added as necessary.
In addition, as a structure of the mobile communication terminal provided with such a function, what was described in FIG. 1 of patent document 1 can be referred, for example.
JP 2007-036975 A

However, the following problems have been pointed out in the wireless relay device and its control method in the above-described conventional mobile communication system. That is, when relaying from one mobile communication terminal 101 to the other mobile radio terminal, bit errors in the uplink and downlink are added, and communication quality degradation may increase.
For example, even if the downlink electric field strength in the direction from the wireless relay apparatus 103 to the mobile communication terminal 102 is sufficiently large and the bit error rate is small (the bit error is small), the mobile communication terminal 101 moves to the wireless relay apparatus 103. When the field strength of the upstream line to reach is weak and as a result, the bit error rate is large, this bit error is transferred to the downlink in the radio relay apparatus 103, and eventually the bit error rate of the received signal in the mobile communication terminal 102 deteriorates. Will be. Also, if there is a bit error in the downlink at this time, that amount is also added, so even if the error correction function in the mobile communication terminal 102 works, if a bit error exceeds the correction capability, In some cases, it was impossible to correct.

  FIG. 7 is a diagram for explaining such a situation. For example, a frame signal as shown in FIG. 7A is transmitted from the mobile communication terminal 101 (digital wireless device A), and the reception state in the wireless relay device 103 is the respective voice channel VCH1 as shown in FIG. Assuming that an X-bit error occurs in VC4 and is relayed as it is, and a Y-bit error occurs in the downlink, the received signal at the mobile communication terminal 102 (digital radio B) is As shown in FIG. 7C, it can be understood that X + Ybit is obtained by adding bit errors of both lines.

In addition, the following problems have been pointed out as other problems. That is, as shown in FIG. 8 (a), the mobile communication terminal 101 (digital radio device A) transmits the voice channels VCH1 to VCH4 in frame 1 (Frame 1) by replacing them with high-speed information channels. Then, when the high-speed information channel does not need to be relayed in the radio relay apparatus 103 and the high-speed information channel is deleted, the signal retransmitted from the radio relay apparatus (digital radio base station) is as shown in FIG. As shown in FIG. 2, the normal voice channels VCH1 to VCH4 are relayed. At this time, the data of the deleted high-speed information channel part is lost, and the data of VCH1 to VCH4 become indefinite values. However, if it is wirelessly relayed as it is, it is demodulated as a bit error in the voice channel of frame 1 shown in FIG. Even when a large amount of noise is not generated, there is a case where an unnatural demodulated sound is generated.
Such a problem may occur not only in a wireless relay device but also in a base station device of a cellular system, a control station device in an MCA system, and the like, particularly when wireless communication means are used for both upper and lower lines. It was.

The present invention has been made in order to solve the problems associated with the conventional wireless relay, and is a wireless relay device capable of reducing bit errors caused by the wireless relay, and control of the wireless relay device. One objective is to provide a method.
Another object of the present invention is to prevent deterioration in communication quality in wireless relay of a signal including a frame in which a plurality of voice channels are replaced with high-speed information channels.

In order to solve such a problem, the present invention provides a wireless relay apparatus according to claim 1, wherein the wireless communication apparatus includes a plurality of mobile communication terminals that transmit or receive an encoded audio signal including error correction. A relay apparatus having a function of receiving a signal transmitted from the mobile communication terminal and a function of decoding a received encoded signal, and re-encoding the output signal of the receiver including error correction And a transmitter having a function of transmitting the re-encoded signal as a modulated signal to a mobile communication terminal.
According to a second aspect of the present invention, in the wireless relay device according to the first aspect, an error rate judging means for comparing an error rate of the received signal decoded by the receiving device with a preset threshold value, and the error rate is equal to or less than the threshold value In this case, the received signal is stored, and this signal is supplied as a modulated signal to the transmitting device. When it is determined that the error rate exceeds a threshold, the stored received signal or a previously prepared silent sound is stored. Transmission signal switching control means for supplying data as a modulation signal to the transmission device.

According to a third aspect of the present invention, in the wireless relay device according to the first or second aspect, at least the error correction for the audio signal is a forward error detection and correction method (FEC), and the error rate determination means is at least the audio signal. And the threshold value is within a correction capability range of forward error rate detection and correction.
The invention according to claim 4 relates to a method for controlling a radio relay apparatus, and relates to a radio relay apparatus in a radio communication system including a plurality of mobile communication terminals that transmit or receive an audio signal encoded including error correction. In the control method, a receiving process for receiving a signal transmitted from the mobile communication terminal, a decoding process for decoding the received encoded signal, and an output signal of the receiving apparatus is re-encoded including error correction. And a re-encoding process and a transmission process having a function of transmitting the re-encoded signal as a modulation signal to the mobile communication terminal.

According to a fifth aspect of the present invention, in the method for controlling a wireless relay device according to the fourth aspect, an error rate determination process for comparing an error rate of a received signal decoded by the receiving device with a preset threshold, When it is determined that the error rate has exceeded the threshold value, the process for storing the received signal when it is equal to or lower than the threshold value, the process for supplying the signal as a modulated signal to the transmitter, and the error rate exceeds the threshold value, And a process of supplying silent audio data prepared in advance as a modulation signal to the transmission apparatus.
The invention according to claim 6 is the method for controlling a wireless relay device according to claim 4 or 5, wherein at least the error correction for the audio signal is a forward error detection correction method (FEC), and the error rate determination process is performed as follows: It is executed for at least an audio signal, and the threshold value is within a correction capability range of forward error rate detection and correction.

  The invention according to claim 7 is a plurality of mobile communication terminals that transmit or receive a frame signal encoded according to a predetermined protocol, and, if necessary, a high-speed information channel instead of a plurality of voice channels in the frame Receiving apparatus including a function of receiving a signal transmitted from the mobile communication terminal and a function of decoding a received encoded signal in a wireless relay apparatus including a mobile communication terminal having a function of transmitting as A transmission device including a function of re-encoding the output signal of the reception device according to the protocol, a function of transmitting the re-encoded signal as a modulation signal to the mobile communication terminal, and high-speed information from the mobile communication terminal. If a frame signal containing a channel is received and the high-speed information channel does not need to be relayed, this high The information channel, characterized by comprising a function for relaying operation sound data of silence of the voice data or the previous frame as the frame data.

Since the present invention is configured or controlled as described above, the following effects can be obtained.
In the wireless relay device according to claim 1, in the wireless relay device between mobile communication terminals that transmits and receives an audio signal encoded including error correction, the received encoded signal is once decoded and further re-encoded. Since it has a function to transmit to the mobile communication terminal above, even if bit errors occur in the uplink, they are corrected so that they are not added to the downlink, improving communication quality It becomes possible to do.
According to a second aspect of the present invention, in the wireless relay device according to the first aspect, the error rate in at least the voice signal of the frame of the signal received by the uplink is compared with a preset threshold value, and the error rate is equal to or less than the threshold value. Stores the audio data of this frame and supplies this signal as a modulated signal to the transmitting apparatus. If the error rate exceeds a threshold value, the stored audio data or Since silent audio data prepared in advance is used as a modulation signal, even if bit errors that cannot be repaired occur on the uplink, these errors are not added to the downlink and communication quality is good. It becomes possible to keep it.

According to a third aspect of the present invention, in the radio relay apparatus according to the first and second aspects, at least error correction for a speech signal is a forward error correction (FEC), and the threshold value is a forward error. Since it is set within the correction capability range of rate detection and correction, it has a high correction capability and the error correction capability can be arbitrarily set.
Since the inventions according to claims 4 to 6 represent the inventions according to claims 1 to 3 as a control method for the wireless relay device, the same effects as the inventions according to claims 1 to 3 can be achieved by implementing the method. Can be obtained. Further, by programming the function or control method of the wireless relay device of the present invention according to an OS that can be controlled by the computer, any computer equipped with the OS can be controlled by the same processing method. Furthermore, by recording such a program in a computer-readable format, the program according to the present invention can be operated anywhere by carrying this recording medium.

  According to a seventh aspect of the present invention, there is provided a radio relay apparatus between mobile communication terminals that transmits and receives an encoded frame signal when a frame signal including a high-speed information channel is received from the mobile communication terminal. If the high-speed information channel is deleted in the wireless relay device, this high-speed information channel is equipped with a function to perform the relay operation using silence voice data or voice data of the previous frame as frame data. Even if it exists, the data in that portion does not become indefinite, and it is possible to prevent deterioration of the call quality.

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings. However, the components, types, combinations, shapes, relative arrangements, and the like described in this embodiment are merely illustrative examples and not intended to limit the scope of the present invention only unless otherwise specified. .
The configuration of the mobile communication terminal used in the present invention does not have to be different from the conventional one. For example, the configuration described in FIG. .

FIG. 1 is a flowchart showing an example of an audio signal encoding and decoding process procedure performed in a mobile communication terminal. The encoding (encoding) process in these transmitting apparatuses and the decoding (decoding) process in the receiving apparatus are performed by a vocoder (abbreviation of Voice Coder: Vo-Coder), and usually a DSP (Digital Signal Processor or Processing) Are often processed by a processing device). For vocoders, a channel type that divides voice into partial frequency bands and transmits the fluctuation characteristics of the partial energy amount in each band, a formant type that transmits only the formant component of the voice, and the like are known.
FIG. 1A shows an encoding procedure (encoding procedure) in a mobile communication terminal. When an analog audio signal converted into an electric signal by a microphone of the mobile communication terminal is acquired (S1), an audio encoding process is performed. After performing (Voice Encode) (S2), the forward error detection correction (FEC) encoding process is performed (S3), the FEC-processed data is set to a required audio channel (S4), and other information Together with the signal, it is supplied as a modulated signal to the transmitter.
Note that the vocoder is related to the encoding / decoding processing of the audio signal, particularly among the encoding of the signal, and needs to be distinguished from the case where the analog signal other than the audio is digitized or digital data is encoded. However, here, it is assumed that the FEC processing is performed on at least the audio signal, and includes the case where the same FEC processing or other error correction is performed on other data. A description of encoding other than the audio signal is omitted.

In this way, at least the side that receives the signal that has been subjected to the FEC process on the audio signal and transmits it is decoded (decoded) according to the procedure shown in FIG. First, the received signal is detected to reproduce symbol data, and a voice channel is extracted from the signal (S5). After FEC decoding processing (S6), voice decoding processing (Voice Decode) is performed ( S7) Playback to voice. The reproduced audio signal is reproduced and output as an acoustic signal from a speaker or the like (S8).
Forward error detection correction (FEC) is a technique in which an error correction code is added to a packet in advance, and even when a packet loss occurs during transfer, the lost packet can be corrected. It is known that the error correction capability (strength) can be arbitrarily set, can be changed, and can be corrected even when half the maximum number of packets are lost.

FIG. 2 is a flowchart showing an embodiment in the case of controlling the wireless relay device based on the present invention. The example illustrated in FIG. 2 is a flow of processing for receiving and retransmitting a signal encoded by the wireless relay device according to the flow illustrated in FIG.
In FIG. 2, the radio relay apparatus amplifies the received radio wave to a required level, detects it after conversion into an intermediate frequency signal as necessary, acquires symbol data, and detects the frame synchronization word to detect the frame. Each channel information and audio channel signal is acquired (S11). Since this FEC is attached to the audio channel, it is decoded (decoded) (S12). An error rate is detected by FEC decoding, and it is determined whether the value is larger or smaller than a preset threshold value (specified value) (S13). The threshold is related to the error correction capability value of the FEC that is set at that time, and is set to be smaller than that. Therefore, when the error correction rate is smaller than the threshold value (when the error is smaller than the specified value), the lost bit value can be repaired (S13, Yes), so that the voice channel signal (data) at that time is FEC processing (FEC Encode) is performed again (S14), and the signal is supplied as a modulation signal of the transmitting apparatus as a signal of a required portion of the radio transmission frame (S15). When the error correction rate is smaller than the threshold value, the FEC decoded data or the re-encoded data is stored in the memory.

On the other hand, if the error correction rate is greater than the threshold value (the error is larger than the specified value) in the determination of the process S13, since the lost bit value cannot be repaired (S13, No), the voice channel at that time Instead of the signal (data), the stored audio channel of the previous frame or a previously prepared silent audio signal (silent pattern) is set. If the stored data is not processed by FEC, the process proceeds to S14 and again Perform FEC processing (FEC Encode).
According to this process, in the radio relay apparatus, lost bit information is once recovered and repaired within a predetermined error rate range by FEC decoding processing, so that error information is not inherited on the downlink, and communication is performed. Good quality can be maintained.

Further, in the present invention, as shown as the second problem of the prior art, a countermeasure for solving the problem when the voice channel is transmitted to the high-speed information channel from the mobile communication terminal (digital radio) is transmitted. If the high-speed information channel does not need to be relayed by the wireless relay device, silence processing or voice data of the previous frame is set as data in the high-speed information channel, and relay processing is performed.
According to this method, when the high-speed information channel is deleted as in the prior art, it is possible to prevent data errors caused by setting indefinite data in the voice channels VCH1 to VCH4 and the occurrence of uncomfortable voice. Thus, it is possible to prevent deterioration of communication quality.

FIG. 3 is a frame configuration diagram for explaining the effects of the two countermeasures described above. It is assumed that the signal shown in FIG. 3A is transmitted from one mobile communication terminal (digital radio device A). In the first frame, two high-speed information channels FCH are transmitted instead of the voice channels VCH1 to VCH4 following the FSW, LI, and SCH, and in the second and third frames, voice signal data is sent to the voice channels VCH1 to VCH4, respectively. Is set and transmitted to the radio relay apparatus via the uplink.
If this signal is received by the wireless relay device, assuming that a bit error X (Xbit error) occurs in the uplink, it is as shown in FIG. If an error bit is corrected by performing an FEC decoding process on the frame signal in accordance with the present invention described above, the bit error X is deleted as shown in FIG. Note that the high-speed information channel FCH in the first frame in FIG. 3 (c) does not need to be relayed, so it is deleted in the wireless relay device, and in that portion, previously prepared silent data or stored Set the voice channel data prior to that.
This frame signal is transmitted from the radio relay apparatus to the other mobile communication terminal (digital radio B) via the downlink. When the bit error of the downlink is Y, the frame signal is shown in FIG. As described above, the bit error X on the uplink is eliminated, and only the bit error on the downlink remains. In addition, since indefinite data is not included in the high-speed information channel FCH portion, there is no occurrence of noise or bit errors based on them. By applying the present invention in this way, it is possible to prevent deterioration of communication quality, which has been a problem in the past.

  FIG. 4 is a main part schematic diagram showing an example of a wireless relay device according to the present invention. The radio relay apparatus shown in FIG. 4 includes a first mixer (MIX) 3 that mixes a high-frequency signal received by an uplink (uplink) antenna 1 with an output of a local oscillator (OSC) 2, and a first mixer based on the output. A band filter (BPF) 4 that passes only the intermediate frequency, a second mixer (MIX) 6 that mixes the output of the band filter 4 and the output of the second local oscillator 5, and a second intermediate frequency signal from the output. A second band filter (BPF) 7 for extracting the output, an FM detector 8 for detecting the output of the filter, and a low-pass filter (LPF) for branching the detected output signal and extracting a DC offset component from one of the signals 9, a subtracter 10 that subtracts a DC offset component included in the detection signal extracted by the low-pass filter 9 from the output signal of the detector 8, and frame synchronization from the output of the subtractor 10 A frame synchronization word detector (FSW synchronization detector) 11 for detecting a mode and generating a synchronization signal, a symbol detector 12 for detecting a symbol value from the frame synchronization word (hereinafter referred to as FSW), and an FEC decoding processing unit 13 and a vocoder unit including an FEC encoding processing unit 14, a control unit (Cont) 15 that performs control related to at least the present invention, a transmission unit 16 that wirelessly relays a signal to a mobile communication terminal via a downlink, and a downlink ( The transmission unit 16 includes a modulation / power amplification unit 17, a transmission mixing unit (MIX) 19, and a transmission stage band-pass filter (BPF) 20.

In this configuration, operations other than the operation of the vocoder unit are well known and will not be described. However, when voice channel data is supplied from the symbol detection unit 12 to the vocoder unit, the FEC is performed according to the flow shown in FIG. The decoding process is performed, the error rate is obtained and compared with a preset threshold value, and the audio channel data supplied to the modulation / power amplification unit 18 is switched and supplied based on whether or not the threshold value is exceeded. To be controlled.
That is, error rate determination means for comparing the error rate of the decoded received signal with a preset threshold value, and when the error rate is equal to or less than the threshold value, the received signal is stored, and this signal is used as a modulation signal in the transmitting unit 16 ( When it is determined that the error rate has exceeded the threshold value, instead of the reception signal at that time, the stored reception signal or previously prepared silent audio data is used as a modulation signal as the modulation unit 16 (transmission). Transmission signal switching control means to be supplied to the apparatus), and error rate determination, switching control, and the like are performed by the control unit (Cont) 15.
Further, as described as the second object, when the high-speed information channel is deleted in the wireless relay device, the control unit 15 also performs control to supply it as voice channel data instead. The control unit 15 includes a readable / writable memory and stores a threshold value to be compared. Further, as a result of FEC decoding processing of the audio channel and comparing it with a threshold value, if it is determined that the error correction range is possible, the audio channel data after error correction is also recorded in the memory inside the control unit 15. This is as described above.

Although an example of the present invention has been described above, it goes without saying that application to other systems and various modifications are possible without being limited to this example.
For example, it is not necessary to limit the configuration of the wireless relay device to the illustrated one, and in various types that have been known in the past or in a new configuration, as described in each claim, the uplink The error correction process such as FEC or the like is performed on at least the audio signal in the received signal by correcting the bit error occurring in the uplink as much as possible, and then the error correction process is performed again. What is necessary is just to retransmit via a downlink.
The communication method may be a simplex method, a duplex method, a half-duplex method, or a mixture thereof. Furthermore, the present invention is not limited to the example in which the error correction decoding / re-decoding process is always executed in the wireless relay device, but may be performed as necessary. That is, in the wireless relay device, the bit error rate of the uplink signal is monitored, and when the error rate is very small, the relay processing is directly performed without performing error correction decoding / re-decoding processing. If the error correction decoding / re-decoding process is performed only when a certain number of bit errors are included, a slight signal delay associated with these processes can be eliminated.

Further, by programming the control method of the wireless relay apparatus of the present invention according to an OS that can be controlled by a computer, any computer equipped with the OS can be controlled by the same processing method. If the recording medium is recorded in a readable format, the program can be operated anywhere by carrying the recording medium.
As a recording medium for storing the program, a semiconductor medium (for example, ROM, nonvolatile memory card, etc.), an optical medium (for example, DVD, MO, MD, CD, etc.), a magnetic medium (for example, magnetic tape, flexible disk, etc.) In addition, the functions of the above-described embodiments are realized not only by executing the loaded program, but with the operating system or other application programs based on the instructions of the program. The case where the functions of the above-described embodiment are realized by jointly processing is also included.

It is a flowchart which shows the example of the vocoder process used for the radio | wireless system which employ | adopts this invention, (a) is an encoding process, (b) is a flowchart of a decoding process. The flowchart which shows an example of the process in the wireless relay apparatus of this invention. 1 is a frame configuration diagram for explaining an example of the present invention, (a) is a frame configuration diagram transmitted from one mobile communication terminal, (b) is a frame configuration diagram of a reception signal of a radio relay apparatus, and (c). FIG. 7 is a frame configuration diagram of FEC re-encoding in the radio relay device, and FIG. 1 is a schematic configuration diagram showing an embodiment of a wireless relay device according to the present invention. The radio | wireless system schematic diagram which shows an example of a mobile communication system. (A) and (b) are figures which show the example of a frame structure in a mobile communication system. It is a figure which shows the example of a frame structure for demonstrating the conventional problem, (a) is a frame block diagram transmitted from one mobile communication terminal, (b) is a frame block diagram of the received signal of a radio relay apparatus, (C) is a frame configuration diagram of a received signal of the mobile communication terminal of the communication partner. It is a figure which shows the example of a frame structure for demonstrating the other conventional problem, (a) is a frame block diagram transmitted from one mobile communication terminal, (b) is a frame structure of the received signal of a radio relay apparatus FIG. 4C is a frame configuration diagram of a received signal of the mobile communication terminal of the communication counterpart.

Explanation of symbols

  11 FSW sync detector, 12 symbol detector, 13 FEC decoder, 14 FEC encoder, 15 controller, FSW frame sync word, LI link information, SCH low speed information, FCH high speed information channel, VCH1 to VCH4 voice channels.

Claims (7)

  A wireless relay apparatus in a wireless communication system including a plurality of mobile communication terminals that transmit or receive an encoded audio signal including error correction, and a function for receiving a signal transmitted from the mobile communication terminal and reception Receiving apparatus having a function of decoding the encoded signal, a function of re-encoding the output signal of the receiving apparatus including error correction, and transmitting the re-encoded signal as a modulation signal to the mobile communication terminal A wireless relay device comprising: a transmission device having a function.   The receiving apparatus compares the error rate of the decoded received signal with a preset threshold value, stores the received signal when the error rate is equal to or less than the threshold value, and uses this signal as a modulation signal A transmission signal switching control means for supplying the transmission apparatus with the stored reception signal or previously prepared silent audio data as a modulation signal when it is determined that the error rate exceeds a threshold value. The wireless relay device according to claim 1, further comprising:   At least the error correction for the audio signal is a forward error detection and correction method (FEC), the error rate determination means is executed for at least the audio signal, and the threshold is within the correction capability range of the forward error rate detection and correction. The wireless relay device according to claim 1, wherein the wireless relay device is provided.   In a method for controlling a radio relay apparatus in a radio communication system including a plurality of mobile communication terminals that transmit or receive an encoded audio signal including error correction, a reception process for receiving a signal transmitted from the mobile communication terminal A decoding process for decoding the received encoded signal, a re-encoding process for re-encoding the output signal of the receiving apparatus including error correction, and a mobile communication terminal using the re-encoded signal as a modulation signal And a transmission process having a function of transmitting to the wireless relay device control method.   An error rate determination process for comparing the error rate of the received signal decoded by the receiving apparatus with a preset threshold value, a process for storing the received signal when the error rate is equal to or lower than the threshold value, and this signal as a modulation signal A process for supplying to the transmission apparatus; and a process for supplying the stored reception signal or previously prepared silent audio data to the transmission apparatus as a modulation signal when the error rate is determined to exceed a threshold value. 5. The method of controlling a wireless relay device according to claim 4, further comprising:   At least the error correction for the audio signal is a forward error detection and correction method (FEC), the error rate determination process is executed for at least the audio signal, and the threshold value is within the correction capability range of the forward error rate detection and correction. 6. The method of controlling a radio relay apparatus according to claim 4 or 5, wherein the radio relay apparatus is controlled. A plurality of mobile communication terminals that transmit or receive frame signals encoded according to a predetermined protocol, and have a function of transmitting as high-speed information channels instead of a plurality of voice channels in a frame as necessary In a wireless relay device in a wireless communication system including a communication terminal,
A receiving device including a function of receiving a signal transmitted from the mobile communication terminal and a function of decoding a received encoded signal; a function of re-encoding an output signal of the receiving device according to the protocol; and A transmission apparatus including a function of transmitting an encoded signal as a modulation signal to a mobile communication terminal;
When a frame signal including a high-speed information channel is received from the mobile communication terminal and it is not necessary to relay the high-speed information channel, silence audio data or audio of a frame received before that is transmitted to the high-speed information channel. A wireless relay device having a function of performing relay operation using data as frame data.

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