JP5389004B2 - Wireless communication apparatus and wireless communication method - Google Patents

Description

  The present invention relates to a wireless communication apparatus and a wireless communication method for performing wireless communication.

  As wireless communication becomes widespread, its demand is increasing. The frequency resources used for wireless communication are limited, and the frequency resources are currently tight. For this reason, improvement in frequency utilization efficiency is demanded. Here, the definition of the frequency utilization efficiency is “(frequency utilization efficiency) = (transmission speed) / (transmission bandwidth)”.

By the way, methods for improving the transmission speed have been actively studied so far. In recent years, as an approach for improving the frequency utilization efficiency while maintaining the transmission rate, a technique for reducing the transmission bandwidth while keeping the transmission rate constant has been studied.
FIG. 5 is a diagram illustrating the concept of a technique for reducing the transmission bandwidth. As shown in the figure, when the transmission side suppresses a part of the transmission spectrum with a filter or the like, the transmission bandwidth, which is the frequency bandwidth used for transmission, can be reduced. Hereinafter, a method for deleting (suppressing) a part of the transmission spectrum in this way is referred to as spectrum compression, and a band of the deleted transmission spectrum (Nyquist band) is referred to as a suppression band. The band ratio is called the suppression rate.

In the above-described method, the frequency bandwidth can be improved because the transmission bandwidth is reduced while keeping the transmission rate constant. However, since the waveform of the reception signal is distorted due to suppression of the transmission spectrum, it is necessary to compensate the waveform distortion on the reception side.
FIG. 6 is a diagram showing the concept of waveform distortion compensation. As shown in the figure, the receiving side needs to restore or estimate the band suppressed on the transmitting side using error correction and compensation for waveform distortion by an equalizer. When using the above-described method, a technique for compensating for the band suppressed on the transmission side is essential.

Further, in the technique described in Non-Patent Document 1, the transmission side communication device takes into account the transmission spectrum in consideration of the reception status and distortion compensation performance (equalizer performance and error correction performance) in the reception side communication device. Suppress both ends. The receiving side performs demodulation processing after restoring the transmission spectrum suppressed on the transmitting side by compensating for waveform distortion using error correction and an equalizer. In this technique, when the transmission spectrum is suppressed, it is necessary to determine the suppression rate in consideration of the reception status and reception performance on the reception side.
The procedure for the communication apparatus on the receiving side to determine the suppression rate and perform communication will be described below.

FIG. 7 is a flowchart showing a procedure for determining a suppression rate in the communication device on the receiving side.
First, the communication device on the receiving side is equipped with the modulation scheme, coding rate, and received SNR (Signal to Noise Ratio) measured at the local station, notified from the communication device on the transmitting side. Based on the performance of the current equalizer and the performance of the error corrector, a recoverable suppression rate is calculated (step S71). The communication device on the reception side transmits information indicating the calculated suppression rate to the communication device on the transmission side (step S72). The communication device on the transmission side suppresses the transmission spectrum using the suppression rate included in the information received from the communication device on the reception side, and performs transmission with a reduced frequency bandwidth (step S73).

Further, in the technique described in Non-Patent Document 2, the channel gain between the transmission side and the reception side is known, and the communication device on the transmission side suppresses the transmission spectrum where the power drops due to frequency selective fading. However, by using a frequency band having a relatively high channel gain for transmission, the received power is improved while reducing the frequency band. Further, the communication device on the receiving side uses the error corrector and the equalizer to compensate the waveform distortion for the received spectrum.
Hereinafter, a procedure in which the communication device on the transmission side determines the suppression rate and performs communication will be described.

FIG. 8 is a flowchart showing a procedure for determining a suppression rate in the communication device on the transmission side.
First, the communication device on the reception side transmits the reception SNR measured at the local station and information indicating the performance of the equalizer and the error correction performance provided to the communication device on the transmission side (step S81). The transmission side communication device receives the received SNR received from the reception side communication device, information indicating the performance of the equalizer and the error correction performance, the modulation scheme used in the local station, and the coding rate. A suppression rate that can be restored by the communication device on the side is calculated (step S82). The communication device on the transmission side performs transmission with the frequency bandwidth reduced by suppressing the transmission spectrum using the calculated suppression rate (step S83).

Yasunori Futaki, Naomasa Yoshida, Masayuki Ariyoshi, “Examination of Partial Spectrum Transmission Method for Dynamic Spectrum Access Application,” IEICE Tech. 1-6, January 2009 Yasuhiko Okada, Shinsuke Ibi, Seiichi Sampei, “Proposal of Spectrum Shaping by Frequency Clipping for Turbo Equalization,” IEICE Technical Report RCS 2006-258, pp. 95-98, March 2007

However, in the technique described in Non-Patent Document 1, it is necessary to calculate a suppression rate based on the channel gain on the reception side and transmit control information indicating the calculated suppression rate to the transmission side. In the technique described in Non-Patent Document 2, it is necessary to transmit control information indicating the distortion compensation performance on the reception side to the transmission side.
Therefore, the above technique may not be used for an existing wireless communication system that does not have a function of transmitting / receiving or decoding the calculated suppression rate and control information indicating the distortion compensation capability on the receiving side.

  The present invention has been made in view of the above situation, and its purpose is to transmit and receive the suppression rate calculated by the reception side and the control information indicating the distortion compensation capability of the reception side between the transmission side and the reception side. It is an object of the present invention to provide a wireless communication apparatus and a wireless communication method that can determine a suppression rate.

  In order to solve the above-described problem, the present invention provides a wireless communication apparatus in a wireless communication system including a plurality of wireless communication apparatuses that perform communication, wherein a spectrum of a transmission signal generated according to an input data sequence is obtained. A transmission band suppression unit that suppresses the transmission signal according to a suppression rate that indicates a ratio of a spectrum bandwidth of the transmission signal to a bandwidth of the spectrum to be suppressed, and a transmission unit that transmits the transmission signal with the spectrum suppressed as a radio signal A response signal detection unit that detects that the transmission signal has been received without error at a transmission destination, and a transmission bandwidth determination unit that determines the suppression rate based on a detection result of the response signal detection unit. The wireless communication apparatus is characterized in that

  In addition, the present invention provides the transmission bandwidth determination unit according to the above-described invention, wherein the transmission bandwidth determination unit sets an initial value of the suppression rate to 1 when determining the suppression rate, and transmits the transmission signal at the transmission destination. Until the transmission signal is transmitted without error, a predetermined amount of change is subtracted from the suppression rate every time the transmission signal is transmitted, and the suppression rate when the transmission signal is received without error at the transmission destination is used for subsequent transmissions. It is characterized by deciding to use.

  In addition, the present invention provides the transmission bandwidth determination unit according to the above-described invention, wherein the transmission bandwidth determination unit sets an initial value of the suppression rate to 0 when determining the suppression rate, and transmits the transmission signal at the transmission destination. Each time the transmission signal is transmitted without error, a predetermined amount of change is added to the suppression rate every time the transmission signal is transmitted, and the suppression rate used in the transmission immediately before the transmission signal is no longer received without error at the transmission destination Is determined to be used for subsequent transmissions.

  Moreover, the present invention is characterized in that, in the above-described invention, the transmission bandwidth determination unit further reduces the amount of change by a predetermined step value each time transmission is performed.

  The present invention also relates to a wireless communication method in a wireless communication system including a plurality of wireless communication devices that perform communication, and a spectrum band for suppressing a spectrum of a transmission signal generated according to an input data sequence. A transmission band suppression step of suppressing the transmission signal according to a suppression rate indicating a ratio of a spectrum bandwidth of the transmission signal to a width, a transmission step of transmitting the transmission signal with the spectrum suppressed as a radio signal, and the transmission signal A radio comprising: a response signal detecting step for detecting that a transmission destination has been received without error; and a transmission bandwidth determining step for determining the suppression rate based on a detection result in the response signal detecting step. It is a communication method.

  Further, the present invention provides the above-described invention, wherein, in the transmission bandwidth determination step, when determining the suppression rate, the initial value of the suppression rate is set to 1, and the transmission signal is transmitted to the transmission destination. Until the transmission signal is transmitted without error, a predetermined amount of change is subtracted from the suppression rate every time the transmission signal is transmitted, and the suppression rate when the transmission signal is received without error at the transmission destination is used for subsequent transmissions. It is characterized by deciding to use.

  Further, the present invention provides the transmission bandwidth determination step according to the above-described invention, wherein, when determining the suppression rate, the initial value of the suppression rate is set to 0, and the transmission signal is transmitted to the transmission destination. Each time the transmission signal is transmitted without error, a predetermined amount of change is added to the suppression rate every time the transmission signal is transmitted, and the suppression rate used in the transmission immediately before the transmission signal is no longer received without error at the transmission destination Is determined to be used for subsequent transmissions.

  Further, the present invention is characterized in that, in the above-described invention, in the transmission bandwidth determination step, the amount of change is reduced by a predetermined step value for each transmission.

  According to the present invention, the radio terminal apparatus determines the suppression rate based on the response signal received as a response to the transmission signal, and therefore transmits and receives control information indicating the suppression rate calculated by the reception side and the distortion compensation capability on the reception side. Without this, the suppression rate can be determined between the transmission side and the reception side.

1 is a schematic block diagram illustrating a configuration of a first wireless communication device 1 on a transmission side according to a first embodiment. 3 is a schematic block diagram illustrating a configuration of a second wireless communication device 5 on the receiving side in the same embodiment. FIG. It is a flowchart which shows the procedure which calculates the suppression rate (alpha) in the same embodiment. It is a flowchart which shows the procedure which calculates the suppression rate (alpha) in 2nd Embodiment. It is a figure which shows the concept of the method of reducing a transmission bandwidth. It is a figure which shows the concept of a waveform distortion compensation. It is a flowchart which shows the procedure which determines the suppression rate in the communication apparatus of the receiving side. It is a flowchart which shows the procedure which determines the suppression rate in the communication apparatus of a transmission side.

  A wireless communication apparatus and a wireless communication method according to an embodiment of the present invention will be described with reference to the drawings. The wireless communication system according to the present embodiment includes a first wireless communication device that is a device that transmits a data sequence, and a second wireless communication device that is a device that receives a data sequence. Hereinafter, the first wireless communication device and the second wireless communication device will be described.

(First embodiment)
FIG. 1 is a schematic block diagram illustrating a configuration of a transmission-side first wireless communication apparatus 1 (hereinafter referred to as a wireless communication apparatus 1) in the first embodiment.
As shown in the figure, the wireless communication apparatus 1 includes a transmission signal generation circuit 11, a retransmission buffer circuit 12, a transmission band suppression circuit 13, a transmission analog processing circuit 14, a transmission / reception switch 15, an antenna 16, a reception analog processing circuit 17, and a demodulation. A circuit 18, an ACK (ACKnowledgement) signal detection circuit 19, and a transmission bandwidth determination circuit 20 are provided.

  The transmission signal generation circuit 11 performs encoding, modulation, D / A (Digital to Analogue) conversion, and the like on a data series input from a higher-level device or the like to generate a transmission signal. In addition, the transmission signal generation circuit 11 outputs a signal indicating the start of transmission to the ACK signal detection circuit 19 in order to start counting the waiting time limit for the ACK signal received from the transmission destination corresponding to the generated transmission signal. . Further, the transmission signal generation circuit 11 stores the generated transmission signal in the retransmission buffer circuit 12 in preparation for retransmission when transmission of the transmission signal fails.

The retransmission buffer circuit 12 stores a transmission signal in preparation for retransmission when transmission of the transmission signal fails. In addition, when a signal indicating that transmission is successful is input from the ACK signal detection circuit 19, the retransmission buffer circuit 12 deletes the stored transmission signal.
The transmission band suppression circuit 13 performs a filtering process on the transmission signal input from the transmission signal generation circuit 11 by using the suppression rate α input from the transmission bandwidth determination circuit 20, and reduces the frequency bandwidth of the transmission signal. Repress. The transmission band suppression circuit 13 reads a transmission signal from the retransmission buffer circuit 12 when a signal indicating a transmission failure is input from the ACK signal detection circuit 19, and a transmission bandwidth determination circuit for the read transmission signal. Filtering processing is performed using the suppression rate α input from 20, and the frequency bandwidth of the transmission signal is suppressed.
The transmission band suppression circuit 13 outputs the suppressed transmission signal to the transmission analog processing circuit 14.

The transmission analog processing circuit 14 performs analog processing such as frequency conversion on the transmission signal filtered by the transmission band suppression circuit 13, and outputs the transmission signal subjected to analog processing to the transmission / reception switch 15.
The transmission / reception switch 15 outputs the signal input from the transmission analog processing circuit 14 to the antenna 16 and transmits it as a radio signal, and outputs the radio signal received by the antenna 16 to the reception analog processing circuit 17 as a reception signal.

The reception analog processing circuit 17 performs frequency conversion, filtering processing, and the like on the reception signal input from the transmission / reception switch 15, converts it to a baseband signal, and outputs this baseband signal to the demodulation circuit 18.
The demodulation circuit 18 performs demodulation, error correction, etc. on the baseband signal input from the reception analog processing circuit 17 to generate a reception data signal, and outputs the generated reception data signal to the ACK signal detection circuit 19. .

  When a signal indicating the start of transmission is input from the transmission signal generation circuit 11, the ACK signal detection circuit 19 sets a value indicating a predetermined waiting period in the timer 191 provided therein, Start counting. Further, when the reception data signal is input from the demodulation circuit 18, the ACK signal detection circuit 19 determines whether or not the input reception data signal includes an ACK signal destined for the own apparatus.

Further, when the ACK signal detection circuit 19 includes an ACK signal addressed to the own device, the ACK signal detection circuit 19 stops counting of the timer 191 and indicates that the ACK signal addressed to the own device is received, that is, the transmission is successful. The signal is output to the retransmission buffer circuit 12 and the transmission bandwidth determination circuit 20.
Further, when the ACK signal detection circuit 19 detects that the waiting time limit has expired based on the count of the timer 191 without receiving the ACK signal addressed to itself, the ACK signal detection circuit 19 transmits a signal indicating that the transmission has failed to the transmission band suppression circuit. 13 and the transmission bandwidth determination circuit 20.
The transmission bandwidth determination circuit 20 calculates a suppression rate α used when the transmission bandwidth suppression circuit 13 suppresses the transmission bandwidth, and outputs the calculated suppression rate α to the transmission bandwidth suppression circuit 13.

  With the above-described configuration, the wireless communication device 1 generates a transmission signal from the input data series, and calculates a suppression rate α using the frequency bandwidth of the transmission signal for suppression based on the ACK signal received from the transmission destination. . Then, the wireless communication device 1 suppresses the frequency bandwidth of the transmission signal using the calculated suppression rate α, and transmits the suppressed transmission signal.

Subsequently, the configuration of the second wireless communication apparatus on the receiving side in the present embodiment will be described.
FIG. 2 is a schematic block diagram showing the configuration of the second wireless communication device 5 (hereinafter referred to as the wireless communication device 5) on the receiving side in the present embodiment. As shown in the figure, the wireless communication device 5 includes an antenna 51, a transmission / reception switch 52, a reception analog processing circuit 53, an equalization circuit 54, a demodulation / decoding circuit 55, an error detection circuit 56, an ACK signal generation circuit 57, and a transmission analog. A processing circuit 58 is provided.

The transmission / reception switch 52 outputs a radio signal received by the antenna 51 to the reception analog processing circuit 53 as a reception signal, and outputs a signal input from the transmission analog processing circuit 58 to the antenna 51 and transmits it as a radio signal.
The reception analog processing circuit 53 performs analog processing such as frequency conversion and filtering processing on the reception signal input from the transmission / reception switch 52 to convert it into a baseband signal, and this baseband signal is input to the equalization circuit 54. Output.

The equalization circuit 54 distorts the baseband signal input from the reception analog processing circuit 53 with distortion caused by processing (spectrum suppression processing) for suppressing the frequency bandwidth in the transmission band suppression circuit 13 of the wireless communication device 1. An equalization process for compensation is performed, and the equalized baseband signal is output to the demodulation and decoding circuit 55. Here, the equalization process performed by the equalization circuit 54 is, for example, an equalization process based on a zero forcing norm, an equalization process based on a least square error norm, an equalization process based on turbo equalization, or the like.
The demodulation decoding circuit 55 performs demodulation processing, error correction decoding processing, and the like on the baseband signal compensated for distortion by the equalization circuit 54, generates a reception data signal, and sends the generated reception data signal to the error detection circuit 56. Output.

When the reception data signal is input from the demodulation and decoding circuit 55, the error detection circuit 56 determines whether or not an error is included in the input reception data signal. For example, the transmission signal generation circuit 11 of the transmission-side wireless communication apparatus 1 inserts an error detection code such as a frame check sequence, and the error detection circuit 56 detects an error by using the inserted error detection code. Can do.
In addition, when the received data signal does not include an error, that is, when the signal transmitted from the wireless communication apparatus 1 is normally received, the error detection circuit 56 transmits a signal indicating that the transmission is successful to the ACK signal. The data is output to the generation circuit 57 and the received data signal is output as a data series to a higher-level device. On the other hand, the error detection circuit 56 ends the process when an error is included in the received data signal.

When the signal indicating that the transmission is successful is input from the error detection circuit 56, the ACK signal generation circuit 57 outputs a predetermined ACK signal to the transmission analog processing circuit 58.
The transmission analog processing circuit 58 performs analog processing such as frequency conversion on the ACK signal input from the ACK signal generation circuit 57, outputs the ACK signal subjected to analog processing to the transmission / reception switch 52, and outputs the ACK signal. It transmits as a radio signal from the antenna 51.

With the above-described configuration, the reception-side wireless communication device 5 can restore the received data signal when the equalization circuit 54 compensates for distortion of the spectrum-suppressed signal in the wireless communication device 1. Further, the wireless communication device 5 determines whether or not an error is included in the restored received data signal. The wireless communication device 5 transmits an ACK signal when an error is included in the received data signal, and does not transmit an ACK signal when an error is included in the received data signal.
That is, the wireless communication device 5 transmits an ACK signal when it can correctly receive a spectrum-suppressed received data signal without error, and does not transmit an ACK signal when it cannot correctly receive a spectrum-suppressed received data signal. . As described above, the wireless communication device 5 indirectly controls the calculation of the suppression rate α used for spectrum suppression in the wireless communication device 1 by selecting whether or not to transmit the ACK signal.

Next, a procedure for calculating the suppression rate α in the wireless communication device 1 will be described.
FIG. 3 is a flowchart showing a procedure for calculating the suppression rate α in the present embodiment.

The transmission bandwidth determination circuit 20 sets the suppression rate α to “1” (100%) as an initial value when communication with the wireless communication device 5 that is the transmission destination of the data series is started (step S11). Here, the suppression rate α = 1 indicates that the entire spectrum of the transmission signal is suppressed.
Then, the transmission bandwidth determination circuit 20 subtracts a predetermined change amount Δα from the suppression rate α, sets the subtraction result to a new suppression rate α, and outputs the new suppression rate α to the transmission bandwidth suppression circuit 13 (step) S12).

  Here, the change amount Δα is a value determined in advance based on a simulation, an actual measurement value, or the like. When the amount of change Δα is a small value, control with a higher resolution of the suppression rate α can be performed, and the frequency utilization efficiency can be further improved. However, it takes time to determine the suppression rate α, and there is a trade-off relationship between the frequency utilization efficiency and the time required to determine the suppression rate α.

The transmission band suppression circuit 13 suppresses the spectrum of the transmission signal using the input suppression rate α, and the transmission signal suppressed by the suppression rate α is transmitted (step S13).
When an ACK signal for the transmission signal transmitted in step S13 is not received and a signal indicating a transmission failure is input from the ACK signal detection circuit 19 (step S14: NO), the transmission bandwidth determination circuit 20 performs processing. Return to step S12. That is, the wireless communication device 1 sets a value obtained by further subtracting the change amount Δα from the suppression rate α to a new suppression rate α, lowers the suppression rate, and transmits a transmission signal again.

On the other hand, when an ACK signal for the transmission signal transmitted in step S13 is received and a signal indicating successful transmission is input from the ACK signal detection circuit 19 (step S14: YES), the transmission bandwidth determination circuit 20 It is determined that communication using the current suppression rate α is possible, the current suppression rate α is determined as the suppression rate α used for transmission, and the process ends.
Thereafter, the wireless communication device 1 transmits a transmission signal whose spectrum is suppressed using the determined suppression rate α.

As described above, the wireless communication device 1 sets the initial value of the suppression rate α to 1 and gradually decreases the suppression rate α every time a transmission signal is transmitted until an ACK signal is received from the wireless communication device 5. Thus, the frequency bandwidth for transmitting the transmission signal is gradually increased. And the radio | wireless communication apparatus 1 determines the suppression rate (alpha) at the time of receiving an ACK signal to the suppression rate used for subsequent transmission.
In other words, the wireless communication device 1 calculates the suppression rate α used for communication with the wireless communication device 5 based on the presence or absence of the ACK signal, that is, the success or failure of transmission, and determines the frequency bandwidth for transmitting the transmission signal. .

Accordingly, without transmitting special control information indicating the suppression rate calculated by the reception-side wireless communication device 5 or special control information such as information indicating the distortion compensation performance of the reception-side wireless communication device 5, The suppression rate α of the spectrum can be calculated.
By using the wireless communication device 1 on the transmission side according to the present embodiment, blind processing without using special control information as described above can be performed, and a transmission signal corresponding to the channel gain between the transmission side and the reception side can be obtained. It is possible to calculate the spectrum suppression rate α for. At this time, the information fed back from the reception-side wireless communication device 5 to the transmission-side wireless communication device 1 is only an ACK signal used in general communication. Therefore, adaptation to an existing communication system is easy.

Further, the frequency bandwidth used between the wireless communication device 1 and the wireless communication device 5 can be reduced according to the calculated suppression rate α, and the frequency use efficiency can be improved.
Further, by appropriately setting the change amount Δα, it is possible to select the largest suppression rate α within a range that can be restored by the receiving-side wireless communication device 5, and to reduce the frequency bandwidth used for transmission to the smallest bandwidth. can do.

(Second Embodiment)
The wireless communication device on the transmission side in the second embodiment is different from the first embodiment in the procedure for calculating the suppression rate α. Further, the configuration of the wireless communication device on the transmission side in the present embodiment is the same as that of the wireless communication device 1 of the first embodiment, and thus the description thereof is omitted.
Hereinafter, a procedure for calculating the suppression rate α in the present embodiment will be described.

FIG. 4 is a flowchart showing a procedure for calculating the suppression rate α in the second embodiment.
The transmission bandwidth determination circuit 20 sets the suppression rate α to “0” (0%) as an initial value when communication with the wireless communication device 5 that is the transmission destination of the data series is started (step S21). Here, the suppression rate α = 0 indicates that the spectrum of the transmission signal is not suppressed.
Then, the transmission bandwidth determination circuit 20 adds a predetermined amount of change Δα to the suppression rate α, sets the addition result as a new suppression rate α, and outputs the new suppression rate α to the transmission bandwidth suppression circuit 13 (step). S22).

The transmission band suppression circuit 13 suppresses the spectrum of the transmission signal using the input suppression rate alpha, and the transmission signal suppressed by the suppression rate α is transmitted (step S23).
When an ACK signal corresponding to the transmission signal transmitted in step S23 is received and a signal indicating successful transmission is input from the ACK signal detection circuit 19 (step S24: YES), the transmission bandwidth determination circuit 20 performs processing. Return to S22. That is, the wireless communication apparatus 1 sets a value obtained by further adding the amount of change Δα to the suppression rate α as a new suppression rate α, and increases the suppression rate to transmit a transmission signal.

On the other hand, when the ACK signal for the transmission signal transmitted in step S13 is not received and a signal indicating a transmission failure is input from the ACK signal detection circuit 19 (step S24: NO), the transmission bandwidth determination circuit 20 It is determined that communication using the current suppression rate α is impossible, and the amount of change Δα is subtracted from the current suppression rate α to return to the suppression rate used for the previous transmission (step S25). The suppression rate α used for the subsequent transmission is determined and the process is terminated.
Thereafter, the wireless communication device 1 transmits a transmission signal whose spectrum is suppressed using the determined suppression rate α.

As described above, the wireless communication device 1 of the second embodiment sets the initial value of the suppression rate α to 0 and suppresses the suppression rate every time a transmission signal is transmitted until no ACK signal is received from the wireless communication device 5. Is gradually increased to gradually reduce the frequency bandwidth for transmitting the transmission signal. The wireless communication device 1 is characterized in that the suppression rate α used in the transmission immediately before the reception of the ACK signal is determined as the suppression rate used for the subsequent transmission.
In other words, the wireless communication device 1 calculates the suppression rate α used for communication with the wireless communication device 5 based on the presence or absence of the ACK signal, that is, the success or failure of transmission, and determines the frequency bandwidth for transmitting the transmission signal. .

Thus, as in the first embodiment, special control information indicating the suppression rate calculated by the reception-side wireless communication device 5 or special information such as information indicating the distortion compensation performance of the reception-side wireless communication device 5 is obtained. The spectrum suppression rate α can be calculated without transmitting control information. Similarly to the first embodiment, the information fed back from the reception-side wireless communication device 5 to the transmission-side wireless communication device 1 is only an ACK signal, and thus can be easily adapted to an existing communication system. is there.
In addition, since the wireless communication device 1 according to the present embodiment sets the initial value of the suppression rate α to “0”, the transmission performed until the suppression rate α is determined is successful, and until the suppression rate α is determined. Thus, the data series can be transmitted and the frequency utilization efficiency can be further improved.

  In the first and second embodiments described above, the configuration for calculating (determining) the suppression rate α using the ACK signal indicating that transmission is successful has been described. However, the present invention is not limited to this, and transmission fails. The suppression rate α may be calculated (determined) using a NACK (Negative ACKnowledgement) signal indicating that the above has been performed.

In the first and second embodiments described above, the change amount Δα is described as a fixed value. However, the present invention is not limited to this, and the change amount Δα may be dynamically changed. For example, in the process of determining the suppression rate α, the change amount Δα may be changed every time transmission is performed. Specifically, in the process of determining the suppression rate α, the amount of change Δα at the first transmission is set to the maximum value, and the value of the amount of change Δα is decreased by a predetermined step value each time transmission is repeated. Also good. At this time, the amount (step value) by which the change amount Δα is changed depends on the distortion compensation performance of the reception-side wireless communication device 5 and the gain between the transmission-side wireless communication device 1 and the reception-side wireless communication device 5. Accordingly, a predetermined value may be used. In addition, a lower limit value may be provided for the change amount Δα so that it does not fall below a certain value.
As a result, the time required to determine the suppression rate α can be shortened while increasing the resolution of the suppression rate α.

  In the first and second embodiments described above, the suppression rate α is described as being calculated (determined) when communication is started. However, the present invention is not limited to this. The suppression rate α may be calculated for each frame. Alternatively, the suppression rate α may be calculated when transmission failures occur continuously a predetermined number of times. Thereby, even when the channel gain changes in mobile communication or the like, the suppression rate α corresponding to the channel gain can be calculated, and the frequency use efficiency can be improved according to the channel gain.

  The procedure for calculating the suppression rate α in the first and second embodiments described above may be switched according to the gain between the wireless communication device 1 on the transmission side and the wireless communication device 5 on the reception side. . For example, when the channel gain is higher than a predetermined threshold, the procedure for calculating the suppression rate α in the first embodiment is used, and when the channel gain is low, the procedure for calculating the suppression rate α in the second embodiment is used. May be. In this way, the suppression rate α can be determined more quickly by switching the procedure for calculating the suppression rate α in accordance with the channel gain.

  In the first and second embodiments described above, the case where the transmitting-side wireless communication device 1 has a configuration for transmitting a data sequence and the receiving-side wireless communication device 5 has a configuration for receiving a data sequence will be described. However, the present invention is not limited to this, and the transmission-side device may have the configurations of the wireless communication device 1 and the wireless communication device 5, and the reception-side device may have the configurations of the wireless communication device 1 and the wireless communication device 5. You may make it provide.

  In addition, the procedure for calculating the suppression rate described in the first and second embodiments is applicable to both communication using a single carrier transmission method and communication using a multicarrier transmission method. . When applied to multi-carrier transmission, processing for multi-carrier processing is performed, for example, by FFT (Fast Fourier Transform) processing before the transmission band suppression circuit 13. The multicarrier transmission signal is stored in the retransmission buffer circuit 12 and input to the transmission band suppression circuit 13. Other operations are the same as in the case of single carrier transmission.

  A program for realizing the function of the transmission bandwidth determination circuit 20 in the present invention is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. The suppression rate α may be determined. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

  The wireless communication device described in the present invention corresponds to the first wireless communication device 1 on the transmission side described in each embodiment, and the transmission unit described in the present invention corresponds to the transmission analog processing circuit 14 described in each embodiment. Correspondingly, the receiving unit for issuing bonds in the present invention corresponds to the reception analog processing circuit 17 described in each embodiment.

1... First wireless communication device (wireless communication device)
5. Second wireless communication device (wireless communication device)
DESCRIPTION OF SYMBOLS 11 ... Transmission signal generation circuit 12 ... Retransmission buffer circuit 13 ... Transmission band suppression circuit 14, 58 ... Transmission analog processing circuit 15, 52 ... Transmission / reception switch 16, 51 ... Antenna 17, 53 ... Reception analog processing circuit 18 ... Demodulation circuit 19 ... ACK signal detection circuit 20 ... Transmission bandwidth determination circuit 54 ... Equalization circuit 55 ... Demodulation decoding circuit 56 ... Error detection circuit 57 ... ACK signal generation circuit 191 ... Timer

Claims (8)

A wireless communication device in a wireless communication system including a plurality of wireless communication devices that perform communication,
A transmission band suppression unit that suppresses the spectrum of the transmission signal generated according to the input data series, according to a suppression rate that indicates a ratio of the bandwidth of the spectrum of the transmission signal to the bandwidth of the spectrum to be suppressed;
A transmission unit that transmits the transmission signal, the spectrum of which is suppressed, as a radio signal;
A response signal detection unit for detecting that the transmission signal is received without error at the transmission destination;
A wireless communication device comprising: a transmission bandwidth determination unit that determines the suppression rate based on a detection result of the response signal detection unit. The wireless communication device according to claim 1,
The transmission bandwidth determination unit
When determining the suppression rate, the initial value of the suppression rate is set to 1, and each time the transmission signal is transmitted without error from the transmission destination, a predetermined value is determined from the suppression rate. Subtract the amount of change,
The wireless communication apparatus, wherein the transmission rate is determined to be used for subsequent transmissions when the transmission signal is received without error at the transmission destination. The wireless communication device according to claim 1,
The transmission bandwidth determination unit
When determining the suppression rate, the initial value of the suppression rate is set to 0, and the transmission rate is set to a predetermined value every time the transmission signal is transmitted until the transmission signal is received without error at the transmission destination. Add the amount of change,
The wireless communication apparatus, wherein the transmission rate is determined to be used for subsequent transmissions in the transmission immediately before the transmission signal is not received without error at the transmission destination. A wireless communication device according to claim 2 or claim 3, wherein
The transmission bandwidth determination unit further reduces the amount of change by a predetermined step value for each transmission. A wireless communication method in a wireless communication system comprising a plurality of wireless communication devices for performing communication,
A transmission band suppression step of suppressing the spectrum of the transmission signal generated according to the input data series according to a suppression rate indicating a ratio of the bandwidth of the spectrum of the transmission signal to the bandwidth of the spectrum to be suppressed;
A transmission step of transmitting the transmission signal whose spectrum is suppressed as a radio signal;
A response signal detection step of detecting that the transmission signal has been received without error at the transmission destination;
A wireless communication method, comprising: a transmission bandwidth determination step for determining the suppression rate based on a detection result in the response signal detection step. The wireless communication method according to claim 5,
In the transmission bandwidth determination step,
When determining the suppression rate, the initial value of the suppression rate is set to 1, and each time the transmission signal is transmitted without error from the transmission destination, a predetermined value is determined from the suppression rate. Subtract the amount of change,
It is determined to use the suppression rate when the transmission signal is received without error at the transmission destination for subsequent transmissions. The wireless communication method according to claim 5,
In the transmission bandwidth determination step,
When determining the suppression rate, the initial value of the suppression rate is set to 0, and the transmission rate is set to a predetermined value every time the transmission signal is transmitted until the transmission signal is received without error at the transmission destination. Add the amount of change,
The wireless communication method according to claim 1, further comprising: determining that the suppression rate used in the transmission immediately before the transmission signal is no longer received without error at the transmission destination is used for subsequent transmissions. A wireless communication method according to claim 6 or 7, wherein
In the transmission bandwidth determination step, the change amount is further reduced by a predetermined step value for each transmission.

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