JP4969807B2 - Wireless communication system, wireless communication terminal device, relay device, and wireless communication method - Google Patents

Description

  The present invention relates to a wireless communication system, a wireless communication terminal device, a relay device, and a wireless communication method that perform communication by wireless communication.

  Conventionally, a wireless communication terminal device such as a mobile phone has been used mainly for performing a call or transmission / reception of an e-mail by sending / receiving voice information. Wireless communication terminal devices that can exchange data have begun to spread. In such a wireless communication terminal device, for example, persons who make a call can make a call while displaying images of their faces on a liquid crystal display.

  In a wireless communication system using this type of wireless communication terminal device, the base station monitors the instantaneous reception quality of the wireless communication terminal device and automatically selects the best modulation scheme and coding rate according to the variation in reception quality. An adaptive modulation and coding system that selects and transmits data is used. Specifically, when the reception quality is good, modulation is performed with a modulation scheme capable of high-speed communication (for example, 16 QAM (16 Quadrature Amplitude Modulation)), and when the reception quality is poor, low-speed modulation is performed. Modulation is performed by a method (for example, QPSK (Quadrature Phase Shift Keying)). As for the coding rate at the time of encoding, a low error correction power is used when the reception quality is good, and a high error correction power is used when the reception quality is bad.

Patent Document 1 below discloses a wireless device that can optimize transmission quality by optimizing reception quality during reception and concentrating radiated power in the direction of arrival of a desired wave during transmission. Yes.
JP 2004-297663 A

  By the way, even if the reception quality is optimized as in the technique disclosed in the above-described Patent Document 1 or the like, the state of the wireless propagation path changes due to the movement of the wireless communication terminal device, and the wireless communication terminal device is stationary. Even in such a case, the state of the wireless propagation path also changes depending on the movement of a moving body such as a car around the vehicle. If fading (a phenomenon in which the signal strength or the like changes significantly in time or space in wireless communication) occurs due to such a cause or other causes, the output is unnecessarily increased in an attempt to optimize reception quality. As a result, there is a problem that power consumption increases or noise (jamming wave) is caused.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a wireless communication system, a wireless communication terminal device, a relay device, and a wireless communication method that can prevent an increase in power consumption and noise. To do.

In order to solve the above problems, the following means are adopted.
The wireless communication system according to the present invention is a wireless communication system in which wireless communication is performed between a base station and a wireless communication terminal apparatus, and at least one of the base station and the wireless communication terminal apparatus has a characteristic variation due to a disturbance of a wireless signal. Based on the detection result of the fluctuation detection unit, a target signal quality determination unit that determines the target signal quality of the radio signal, and transmits the radio signal so that the signal quality becomes the target signal quality An output control unit that controls output of a radio signal, and the target signal quality is set to the first value when the first value indicating the characteristic variation is greater than the second value. The quality is set to be lower than the target signal quality set to the second value .
The output control unit determines a target output of a radio signal to be transmitted based on a difference between the target signal quality determined by the target signal quality determination unit and quality information indicating the quality of the radio signal, and transmits the radio signal The output is controlled so as to be the target output.
The fluctuation detecting unit detects a Doppler frequency of the radio signal as a characteristic fluctuation of the radio signal.
The fluctuation detecting unit detects fading of the radio signal as a characteristic fluctuation of the radio signal.
The base station and the wireless communication terminal device include a quality information calculation unit that calculates the quality information from the received radio signal.
The base station and the wireless communication terminal device each include a transmission unit that transmits the quality information calculated by the quality information calculation unit to the other party.
The base station and the wireless communication terminal device include an extraction unit that extracts the quality information transmitted from the counterpart side.
The fluctuation detecting unit includes a moving speed detecting unit that detects a moving speed of the wireless communication terminal device, and determines the target signal quality according to the moving speed detected by the moving speed detecting unit. And
A wireless communication terminal apparatus according to the present invention is a wireless communication terminal apparatus that performs wireless communication with a base station, based on a fluctuation detection unit that detects characteristic fluctuation due to disturbance of a radio signal, and a detection result of the fluctuation detection unit. Te, comprising: a target signal quality determining unit for determining a target signal quality of the radio signal, and an output control section for controlling the output of the radio signal to be transmitted to the signal quality of the radio signal becomes the target signal quality, and the target When the first value indicating the characteristic variation is larger than the second value, the target signal quality set to the first value is lower than the target signal quality set to the second value. It is set so that it becomes .
The relay device according to the present invention is a relay device that performs wireless communication with a wireless communication terminal device, based on a variation detection unit that detects characteristic variation due to disturbance of a radio signal, and a detection result of the variation detection unit, comprising a target signal quality determining unit for determining a target signal quality of the radio signal, and an output control section for controlling the output of the radio signal to be transmitted to the signal quality of the radio signal becomes the target signal quality, and the target signal quality When the first value indicating the characteristic variation becomes larger than the second value, the target signal quality set to the first value becomes lower than the target signal quality set to the second value. It is characterized by being set .
A wireless communication method according to the present invention is a wireless communication method used in a wireless communication system that performs wireless communication between a base station and a wireless communication terminal apparatus, and is a first step of detecting characteristic fluctuation due to disturbance of a wireless signal. And a second step of determining the target signal quality of the radio signal based on the detection result of the first step, and a second step of controlling the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the target signal quality. 3 and steps, only containing the target signal quality, the first value indicating the characteristic fluctuation is greater than the second value, the target signal quality is set to the first value, the second It is set to be lower than the target signal quality set to the value .

  According to the present invention, characteristic variation due to disturbance of a received radio signal is detected, and based on the detection result, the target signal quality of the radio signal to be transmitted is determined, and the signal quality of the radio signal to be transmitted is the target signal quality. Since the output of the wireless signal to be transmitted is controlled so as to satisfy the following condition, the output does not increase unnecessarily even if characteristic fluctuation due to disturbance of the received wireless signal occurs. For this reason, power consumption can be suppressed, and an increase in noise (interfering radio waves) can be prevented.

  Hereinafter, a wireless communication system, a wireless communication terminal device, a relay device, and a wireless communication method according to embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram illustrating configurations of a wireless communication system, a wireless communication terminal device, and a relay device according to the first embodiment of the present invention. As shown in FIG. 1, the wireless communication system of the present embodiment includes a base station 1 and a mobile station 2 as a wireless communication terminal device, and wireless communication is performed between the base station 1 and the mobile station 2. Is called. Communication between a user of the mobile station 2 and a user of another mobile station (not shown) is performed via the base station 1. Although the base station 1 often performs wireless communication with a plurality of mobile stations at a time, only one mobile station 2 is shown in FIG. 1 for the sake of simplicity of explanation. In the following description, for convenience of explanation, the signal flow from the base station 1 to the mobile station 2 is “downlink”, and the signal flow from the mobile station 2 to the base station 1 is “uplink”.

  The base station 1 includes an antenna 11, a radio reception unit 12, a demodulation unit 13, a decoding unit 14, a downlink SINR report value extraction unit 15, an uplink SINR value calculation unit 16, a Doppler frequency detection unit 17, a target SINR value determination unit 18, An output control unit 19, an encoding unit 20, a modulation unit 21, and a wireless transmission unit 22 are configured. The antenna 11 receives a radio wave transmitted from the mobile station 2 and transmits a signal to be transmitted to the mobile station 2 on the radio wave. The wireless reception unit 12 performs processing such as frequency conversion of a signal received by the antenna 11 and outputs the result to the demodulation unit 13. The demodulator 13 demodulates the signal from the radio receiver 12 and outputs the demodulated signal to the decoder 14 and the uplink SINR value calculator 16. The decoding unit 14 decodes the demodulated signal from the demodulation unit 13.

  The downlink SINR report value extraction unit 15 extracts the downlink SINR report value included in the decoded signal decoded by the decoding unit 14. Here, the SINR value is a value indicating a signal-to-interference and noise ratio, and is quality information indicating the quality of a radio signal transmitted and received between the base station 1 and the mobile station 2. It is. Although details will be described later, the mobile station 2 receives a radio signal from the base station 1 and calculates (estimates) a downlink SINR value which is quality information indicating the quality. The base station 1 receives the radio signal from the mobile station 2. And an uplink SINR value, which is quality information indicating the quality, is calculated (estimated). The downlink SINR value calculated by the mobile station 2 is transmitted (reported) to the base station 11 and extracted as a downlink SINR report value by the downlink SINR report value extraction unit 15. The uplink SINR value calculation unit 16 provided in the base station 1 calculates the uplink SINR value using the demodulated signal output from the demodulation unit 13.

  The Doppler frequency detection unit 17 detects the Doppler frequency as a characteristic variation due to disturbance of the radio signal received by the antenna 11 from the demodulated signal from the demodulation unit 13. Here, when the mobile station 2 is moving relative to the base station 1 or both the base station 1 and the mobile station 2 are stationary, there are moving objects such as cars around them. In some cases, the frequency of the radio signal transmitted from the mobile station 2 varies due to the Doppler phenomenon. When such a phenomenon occurs, the SINR value on the radio signal receiving side may be saturated.

  FIG. 2 is a diagram illustrating the relationship between the transmission-side SINR value and the reception-side SINR side. When the base station 1 and the mobile station 2 are both stationary and the Doppler phenomenon due to surrounding environmental fluctuations does not occur, as shown in FIG. The receiving side SINR value rises almost proportionally. Therefore, if the receiving side SINR value is set to a certain target SINR value on the receiving side and the transmission output of the radio signal on the transmitting side is controlled so as to obtain this target SINR value, efficient communication can be performed.

  However, for example, when the mobile station 2 is moving at a high speed, as shown in FIG. 2B, if the transmission side SINR value exceeds a certain value, the reception side SINR value is increased even if the transmission side SINR value is increased. Saturates and does not rise. For this reason, a situation occurs in which the target SINR value cannot be obtained even if the transmission output of the radio signal is maximized on the transmission side (mobile station 2). In such a situation, the radio signal transmitted at the maximum output from the mobile station 2 acts as a disturbing radio wave for other mobile stations, so the data transmission rate (data rate) at the other mobile stations is low. The frequency utilization efficiency may decrease. Further, since transmission is performed at the maximum output, the power consumption increases.

  For this reason, the base station 1 of the present embodiment detects the Doppler frequency by the Doppler frequency detection unit 17 in order to obtain the degree of influence of the Doppler phenomenon. Here, the Doppler frequency is calculated using, for example, normalized inner product values reported by Hidehiro Ando et al., “Doppler frequency detection using pilot symbols”, 2000 Shinsei Conference, B-5-59, 2000, etc. Can be detected. FIG. 3 is a diagram for explaining a method of detecting a Doppler frequency using a normalized inner product value. In FIG. 3, the horizontal axis represents the I-phase component in phase with the carrier wave of the radio signal, and the vertical axis represents the Q-phase component orthogonal to the carrier wave phase.

  For example, when the wireless communication system shown in FIG. 1 uses a W-CDMA (Wideband Code Division Multiple Access) scheme, a plurality of I / Q code multiplexes that are continuously present in the first part in each slot of the uplink. A normalized dot product value is calculated using the pilot signal. The channel estimation value of each slot is calculated from the average value of the pilot symbols of each slot, and the normalized inner product value of the channel estimation values of adjacent slots or slots separated by a plurality of slots is calculated.

FIG. 3 shows the channel estimation values for each slot as averaged received signal points P1 and P2. Here, the normalized inner product value is a cosine value cos θ of the phase change amount θ from the averaged reception signal point P1 to the next averaged reception signal point P2 as viewed from the origin O. If the averaged received signal point P1 vector and its components are a (x ₁ , y ₁ ), and the averaged received signal point P2 vector and its components are b (x ₂ , y ₂ ), then It is expressed by a formula.
Normalized inner product value cos θ = (x ₁ x ₂ + y ₁ y ₂ ) / {(x ₁ ² + y ₁ ² ) (x ₂ ² + y ₂ ² )} ^1/2

Since the calculated normalized inner product value is affected by noise and interference, the influence is reduced by averaging over a plurality of slots. Next, using the calculated normalized inner product value, the maximum Doppler frequency is detected with reference to the relational expression between the normalized inner product value obtained in advance and the maximum Doppler frequency shown below.
f _d = V / λ
Here, V is the moving speed of the mobile station, and λ is the wavelength of the radio wave used.

  Returning to FIG. 1, the target SINR value determination unit 18 determines the target SINR value based on the detection result of the Doppler frequency detection unit 17. Here, the target SINR value indicates the target signal quality of the received radio signal. FIG. 4 is a diagram illustrating an example of the relationship between the Doppler frequency and the determined target SINR value. As shown in FIG. 4, when the Doppler frequency detected by the Doppler frequency detector 17 is lower than f1, the target SINR value determiner 18 sets the target SINR value to T1.

  When the Doppler frequency detected by the Doppler frequency detection unit 17 is not less than f1 and not more than f2, the target SINR value determination unit 18 has a target SINR value lower than T1 according to the detected Doppler frequency. Value. Furthermore, when the Doppler frequency detected by the Doppler frequency detection unit 17 is f2 or more, the target SINR value determination unit 18 sets the target SINR value to T2, which is lower than T1. Thus, as the Doppler frequency increases (the moving speed of the mobile station 2 increases), the target SINR value is determined to be a lower value.

  The output control unit 19 controls the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the signal quality indicated by the target SINR value determined by the target SINR determination unit 18. Specifically, the difference between the target SINR value determined by the target SINR determination unit 18 and the downlink SINR report value extracted by the downlink SINR report value extraction unit 15 is obtained, and the increase / decrease amount of the radio signal transmitted from this difference To determine the target output, and control so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 19 controls the output of the radio signal by performing control for changing the modulation scheme in the modulation unit 21 or performing control for changing the gain of the radio transmission unit 22.

  Note that the uplink SINR value calculated (estimated) by the uplink SINR value calculation unit 16 may be included in the transmission data via the output control unit 19 and input to the encoding unit 20. Thereby, the uplink SINR value calculated based on the radio signal from the mobile station 2 can be transmitted (reported) to the mobile station 2.

  The encoding unit 20 encodes transmission data to be transmitted to the mobile station 2 and outputs it to the modulation unit 21. The modulation unit 21 performs processing such as modulation of input data and outputs the processed data to the wireless transmission unit 22. The modulation unit 21 modulates data input by a modulation method such as 16QAM or QPSK. The wireless transmission unit 22 performs processing such as frequency conversion on the signal modulated by the modulation unit 21 and outputs the result to the antenna 11.

  The mobile station 2 includes an antenna 31, a radio reception unit 32, a demodulation unit 33, a decoding unit 34, a downlink SINR value calculation unit 35, an output control unit 36, an encoding unit 37, a modulation unit 38, and a radio transmission unit 39. Consists of. The antenna 31 receives a radio wave transmitted from the base station 1 and transmits a signal to be transmitted to the base station 1 on the radio wave. The wireless reception unit 32 performs processing such as frequency conversion of a signal received by the antenna 31 and outputs the processed signal to the demodulation unit 33. The demodulator 33 demodulates the signal from the radio receiver 32 and outputs the demodulated signal to the decoder 34 and the downlink SINR value calculator 35. The decoding unit 34 decodes the demodulated signal from the demodulation unit 33.

  The downlink SINR value calculation unit 35 calculates (estimates) a downlink SINR value, which is quality information indicating the quality of the radio signal from the base station 1, using the demodulated signal output from the demodulation unit 33. The downlink SINR value calculated by the downlink SINR value calculation unit 35 is output to the encoding unit 37 while being included in the transmission data. Thereby, the downlink SINR value calculated based on the radio signal from the base station 1 can be transmitted (reported) to the base station 1.

  The output control unit 36 controls the output of the radio signal transmitted by the mobile station 2 by controlling the modulation unit 38 and the radio transmission unit 39 using the decoded signal from the decoding unit 34. The encoding unit 37 encodes transmission data to be transmitted to the base station 1 and outputs it to the modulation unit 38. The modulation unit 38 performs processing such as modulation of input data and outputs the processed data to the wireless transmission unit 39. The modulation unit 38 modulates data input by a modulation method such as 16QAM or QPSK, for example, and the modulation type is controlled by the output control unit 36. The wireless transmission unit 39 performs processing such as frequency conversion on the signal modulated by the modulation unit 38 and outputs the result to the antenna 31. The gain of the wireless transmission unit 39 is controlled by the output control unit 36.

  Next, the operation at the time of communication between the base station 1 and the mobile station 2 in the above configuration will be described. FIG. 5 is a timing chart for explaining operations of the wireless communication system, the wireless communication terminal apparatus, and the relay apparatus according to the first embodiment of the present invention. When a radio signal is transmitted from the base station 1 to the mobile station 2 (step S11), the radio signal is received by the antenna 31 provided in the mobile station 2. The signal received by the antenna 31 is subjected to processing such as frequency conversion by the radio reception unit 32 and demodulated by the demodulation unit 33. The demodulated signal from the demodulator 33 is output to the decoder 34 and the downlink SINR value calculator 35.

  When the demodulated signal from demodulator 33 is input, downlink SINR value calculator 35 calculates (estimates) a downlink SINR value, which is quality information indicating the quality of the radio signal from base station 1, using this demodulated signal. (Step S12). The calculated downlink SINR value is output to the encoding unit 37 while being included in the transmission data, and is transmitted to the base station 1 via the modulation unit 38, the wireless transmission unit 39, and the antenna 31 (step S13). The modulation method in the modulation unit 38 and the gain of the wireless transmission unit 39 during transmission data transmission are controlled by the output control unit 36.

  A radio signal from the mobile station 2 is received by the antenna 11 provided in the base station 11. The signal received by the antenna 11 is subjected to processing such as frequency conversion by the radio reception unit 12 and demodulated by the demodulation unit 13. The demodulated signal from the demodulator 33 is output to the decoder 14, the uplink SINR value calculator 16, and the Doppler frequency detector 17. The uplink SINR value is calculated (estimated) from the demodulated signal input to the uplink SINR value calculating unit 16, and the Doppler frequency is calculated from the demodulated signal input to the Doppler frequency detecting unit 17 (step S14).

  When the demodulated signal is input to the decoding unit 14, the demodulated signal is decoded by the decoding unit 14 and output to the downlink SINR report value extraction unit 15. Then, the downlink SINR report value included in the decoded signal is extracted. The uplink SINR value calculated by the uplink SINR value calculation unit 16 and the downlink SINR report value extracted by the downlink SINR report value extraction unit 15 are output to the output control unit 19 and stored in the output control unit 19. And the downlink SINR value is updated (step S15).

  The detection result of the Doppler frequency detection unit 17 is output to the target SINR value determination unit 18. The target SINR value determination unit 18 determines a target SINR value based on the detection result. For example, as described with reference to FIG. 4, when the Doppler frequency detected by the Doppler frequency detector 17 is low, the target SINR value is set to T1, and when the Doppler frequency detected by the Doppler frequency detector 17 is high. Sets the target SINR value to T2, which is lower than T1. The target SINR value determined by the target SINR value determination unit 18 is output to the output control unit 19.

  The output control unit 19 transmits so that the signal quality of the radio signal to be transmitted (that is, the radio signal received by the mobile station 2) becomes the signal quality indicated by the target SINR value determined by the target SINR value determination unit 18. Control the output of radio signals. Specifically, the difference between the input target SINR value and the downlink SINR report value extracted by the downlink SINR report value extraction unit 15 is obtained, and the output increase / decrease amount of the radio signal to be transmitted is obtained from this difference to obtain the target output. And control so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 19 controls the output of the radio signal by performing control for changing the modulation method in the modulation unit 21 or performing control for changing the gain of the radio transmission unit 22 (step S16).

  When the above processing is completed, the base station 1 transmits information indicating the modulation scheme in the modulation unit 21 and the uplink transmission output set in the radio transmission unit 22 to the mobile station 2 (step S17). As a result, the modulation scheme and transmission output used by the base station 1 during transmission can be known on the mobile station 2 side.

  As described above, in the present embodiment, the target SINR value is determined according to the Doppler frequency detected by the Doppler frequency detection unit 17, and the radio signal is transmitted from the base station 1 using the determined target SINR value. The output is controlled. Here, the target SINR value is higher when the Doppler frequency is higher than the value set when the Doppler frequency is low (for example, when the mobile station 2 is moving at a low speed) (for example, when the mobile station 2 moves at high speed). Is set to be lower. As a result, when the mobile station 2 moves at a high speed, the output is not increased unnecessarily, and as a result, power consumption can be suppressed and an increase in noise (interfering radio waves) can be prevented.

[Second Embodiment]
FIG. 6 is a block diagram illustrating configurations of a wireless communication system, a wireless communication terminal device, and a relay device according to the second embodiment of the present invention. In FIG. 6, the same blocks as those shown in FIG. As shown in FIG. 6, the wireless communication system of this embodiment includes a base station 3 and a mobile station 4 as a wireless communication terminal device, and wireless communication is performed between the base station 3 and the mobile station 4. Is called.

  The base station 3 includes an antenna 11, a radio reception unit 12, a demodulation unit 13, a decoding unit 14, an uplink SINR value calculation unit 16, an output control unit 23, an encoding unit 20, a modulation unit 21, and a radio transmission unit 22. Consists of. The base station 2 shown in FIG. 6 is different from the base station 1 shown in FIG. 1 in that the downlink SINR report value extraction unit 15, the Doppler frequency detection unit 17, and the target SINR value determination unit 18 in FIG. It is the point provided with the output control part 23 instead of the output control part 19 in the inside. The difference is that the calculation result of the uplink SINR value calculation unit 16 is output to the encoding unit 20 without passing through the output control unit 23. The output control unit 23 uses the decoded signal from the decoding unit 14 to control the modulation unit 21 and the wireless transmission unit 22 to control the output of the wireless signal to be transmitted. 19 and different.

The mobile station 4 includes an antenna 31, a radio reception unit 32, a demodulation unit 33, a decoding unit 34, a downlink SINR value calculation unit 35, an uplink SINR report value extraction unit 40, a Doppler frequency detection unit 41, and a target SINR value determination unit. 42, an output control unit 43, an encoding unit 37, a modulation unit 38, and a wireless transmission unit 39. The mobile station 4 shown in FIG. 6 is different from the mobile station 2 shown in FIG. 1 in that an output control unit 43 is provided instead of the output control unit 36 in FIG. This is the point that a Doppler frequency detection unit 41 and a target SINR value determination unit 42 are provided. The difference is that the calculation result of the downlink SINR value calculation unit 35 is output to the output control unit 43.
Another difference is that an uplink SINR report value extraction unit 40 is provided between the decoding unit 34 and the output control unit 43.

  The uplink SINR report value extraction unit 40 extracts the uplink SINR report value included in the decoded signal decoded by the decoding unit 34. The Doppler frequency detection unit 41 is the same as the Doppler frequency detection unit 17 provided in the base station 1 shown in FIG. 1, and as characteristic fluctuation due to disturbance of a radio signal received by the antenna 31 from the demodulated signal from the demodulation unit 33. To detect the Doppler frequency. The target SINR value determination unit 42 is the same as the target SINR value determination unit 18 provided in the base station 1 shown in FIG. 1 and determines the target SINR value based on the detection result of the Doppler frequency detection unit 41. Specifically, the target SINR value is determined using the relationship between the Doppler frequency and the target SINR value shown in FIG.

  The output control unit 43 is the same as the output control unit 19 provided in the base station 1 shown in FIG. 1, and the signal quality of the radio signal to be transmitted (that is, the radio signal received by the base station 3) is the target SINR. The output of the radio signal to be transmitted is controlled so that the signal quality indicated by the target SINR value determined by the determination unit 42 is obtained. Specifically, the difference between the target SINR value determined by the target SINR determination unit 42 and the uplink SINR report value extracted by the uplink SINR report value extraction unit 40 is obtained, and the output increase / decrease of the radio signal to be transmitted is determined from this difference. The target output is determined by obtaining the amount, and control is performed so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 43 controls the output of the radio signal by performing control for changing the modulation method in the modulation unit 28 or performing control for changing the gain of the radio transmission unit 39.

  Note that the downlink SINR value calculated by the downlink SINR value calculation unit 35 may be included in the transmission data via the output control unit 43 and input to the encoding unit 37. Thereby, the downlink SINR value calculated based on the radio signal from the base station 3 can be transmitted (reported) to the base station 3.

  Next, the operation at the time of communication between the base station 3 and the mobile station 4 in the above configuration will be described. FIG. 7 is a timing chart for explaining operations of the wireless communication system, the wireless communication terminal device, and the relay device according to the second embodiment of the present invention. When a radio signal is transmitted from the mobile station 4 to the base station 3 (step S21), the radio signal is received by the antenna 11 provided in the base station 3. The signal received by the antenna 11 is subjected to processing such as frequency conversion by the radio reception unit 12 and demodulated by the demodulation unit 13. The demodulated signal from the demodulator 13 is output to the decoder 13 and the uplink SINR value calculator 16.

  When the demodulated signal from demodulator 13 is input, uplink SINR value calculator 16 uses this demodulated signal to calculate an uplink SINR value that is quality information indicating the quality of the radio signal from mobile station 4 (step S22). ). The calculated uplink SINR value is output to the encoding unit 20 while being included in the transmission data, and is transmitted to the mobile station 4 via the modulation unit 21, the wireless transmission unit 22, and the antenna 11 (step). S23). The modulation method in the modulation unit 21 and the gain of the wireless transmission unit 22 during transmission data transmission are controlled by the output control unit 23.

  A radio signal from the base station 3 is received by an antenna 31 provided in the mobile station 4. The signal received by the antenna 31 is subjected to processing such as frequency conversion by the radio reception unit 32 and demodulated by the demodulation unit 33. The demodulated signal from the demodulator 33 is output to the decoder 34, the downlink SINR value calculator 35, and the Doppler frequency detector 41. A downlink SINR value is calculated from the demodulated signal input to the downlink SINR value calculator 35, and a Doppler frequency is calculated from the demodulated signal input to the Doppler frequency detector 41 (step S24).

  When the demodulated signal is input to the decoding unit 34, the demodulated signal is decoded by the decoding unit 34 and output to the uplink SINR report value extraction unit 40. Then, the uplink SINR report value included in the decoded signal is extracted. The downlink SINR value calculated by the downlink SINR value calculation unit 35 and the uplink SINR report value extracted by the uplink SINR report value extraction unit 40 are output to the output control unit 43 and stored in the output control unit 43. And the uplink SINR value are respectively updated (step S25).

  The detection result of the Doppler frequency detection unit 41 is output to the target SINR value determination unit 42. The target SINR value determination unit 42 determines a target SINR value based on the detection result. For example, as described with reference to FIG. 4, when the Doppler frequency detected by the Doppler frequency detector 41 is low, the target SINR value is set to T1, and when the Doppler frequency detected by the Doppler frequency detector 41 is high. Sets the target SINR value to T2, which is lower than T1. The target SINR value determined by the target SINR value determination unit 42 is output to the output control unit 43.

  The output control unit 43 transmits the signal quality of the radio signal to be transmitted (that is, the radio signal received by the base station 3) to be the signal quality indicated by the target SINR value determined by the target SINR value determination unit 42. Control the output of radio signals. Specifically, the difference between the input target SINR value and the uplink SINR report value extracted by the uplink SINR report value extraction unit 40 is obtained, and the output increase / decrease amount of the radio signal to be transmitted is obtained from this difference to obtain the target output. And control so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 43 controls the output of the radio signal by performing control to change the modulation method in the modulation unit 38 or by controlling to change the gain of the radio transmission unit 39 (step S26).

  When the above processing is completed, the mobile station 4 transmits information indicating the modulation scheme in the modulation unit 38 and the uplink transmission output set by the radio transmission unit 39 to the base station 3 (step S27). As a result, the base station 3 can know the modulation scheme and transmission output used by the mobile station 4 during transmission. As described above, in the present embodiment, the target SINR value is determined according to the Doppler frequency detected by the Doppler frequency detection unit 41 of the mobile station 4, and the mobile station 4 uses the determined target SINR value. Controls the transmission output of radio signals. For this reason, also in this embodiment, power consumption can be suppressed and an increase in noise (interfering radio waves) can be prevented.

[Third Embodiment]
FIG. 8 is a block diagram illustrating configurations of a wireless communication system, a wireless communication terminal device, and a relay device according to the third embodiment of the present invention. In FIG. 8, the same blocks as those shown in FIG. 1 or 6 are denoted by the same reference numerals. As shown in FIG. 8, the wireless communication system of this embodiment includes a base station 5 and a mobile station 6 as a wireless communication terminal device, and wireless communication is performed between the base station 5 and the mobile station 6. Is called.

  The base station 5 shown in FIG. 8 has almost the same configuration as the base station 1 shown in FIG. 1, and the mobile station 6 shown in FIG. 8 has almost the same configuration as the mobile station 4 shown in FIG. The base station 5 shown in FIG. 8 differs from the base station 1 shown in FIG. 1 in that the calculation result of the uplink SINR value calculation unit 16 is output to the encoding unit 20 without passing through the output control unit 19. The mobile station 6 shown in FIG. 8 is different from the mobile station 4 shown in FIG. 1 in that the calculation result of the downlink SINR value calculation unit 35 is output to the encoding unit 37 without passing through the output control unit 43.

  Next, the operation at the time of communication between the base station 5 and the mobile station 6 in the above configuration will be described. FIG. 9 is a timing chart for explaining operations of the wireless communication system, the wireless communication terminal device, and the relay device according to the third embodiment of the present invention. When a radio signal is transmitted from the base station 5 to the mobile station 6 (step S11), the radio signal is received by the antenna 31 provided in the mobile station 6. Here, the uplink SINR value calculated by the uplink SINR value calculation unit 16 of the base station 5 is included in the transmission data, and this uplink SINR value is also included in the radio signal transmitted from the base station 5. To do.

  The signal received by the antenna 31 is subjected to processing such as frequency conversion by the radio reception unit 32 and demodulated by the demodulation unit 33. The demodulated signal from the demodulator 33 is output to the decoder 34, the downlink SINR value calculator 35, and the Doppler frequency detector 41. A downlink SINR value is calculated from the demodulated signal input to the downlink SINR value calculator 35, and a Doppler frequency is calculated from the demodulated signal input to the Doppler frequency detector 41 (step S32). The downlink SINR value calculated by the downlink SINR value calculation unit 35 is input to the encoding unit 37 while being included in the transmission data.

  When the demodulated signal is input to the decoding unit 34, the demodulated signal is decoded by the decoding unit 34 and output to the uplink SINR report value extraction unit 40. Then, the uplink SINR report value included in the decoded signal is extracted. The uplink SINR report value extracted by the uplink SINR report value extraction unit 40 is output to the output control unit 43, and the uplink SINR value stored in the output control unit 43 is updated (step S33).

  The detection result of the Doppler frequency detection unit 41 is output to the target SINR value determination unit 42. The target SINR value determination unit 42 determines a target SINR value based on the detection result. For example, as described with reference to FIG. 4, when the Doppler frequency detected by the Doppler frequency detector 41 is low, the target SINR value is set to T1, and when the Doppler frequency detected by the Doppler frequency detector 41 is high. Sets the target SINR value to T2, which is lower than T1. The target SINR value determined by the target SINR value determination unit 42 is output to the output control unit 43.

  The output control unit 43 transmits so that the signal quality of the radio signal to be transmitted (that is, the radio signal received by the base station 5) becomes the signal quality indicated by the target SINR value determined by the target SINR value determination unit 42. Control the output of radio signals. Specifically, the difference between the input target SINR value and the uplink SINR report value extracted by the uplink SINR report value extraction unit 40 is obtained, and the output increase / decrease amount of the radio signal to be transmitted is obtained from this difference to obtain the target output. And control so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 43 controls the output of the radio signal by performing control to change the modulation method in the modulation unit 38, or performing control to change the gain of the radio transmission unit 39 (step S34). When the above processing is completed, a radio signal including a downlink SINR value is transmitted from the mobile station 6 to the base station 5 (step S35).

  A radio signal transmitted from the mobile station 6 is received by an antenna 11 provided in the base station 5. The signal received by the antenna 11 is subjected to processing such as frequency conversion by the radio reception unit 12 and demodulated by the demodulation unit 13. The demodulated signal from the demodulator 13 is output to the decoder 14, the uplink SINR value calculator 16, and the Doppler frequency detector 17. The uplink SINR value is calculated from the demodulated signal input to the uplink SINR value calculating unit 16, and the Doppler frequency is calculated from the demodulated signal input to the Doppler frequency detecting unit 17 (step S36). The downlink SINR value calculated by the uplink SINR value calculation unit 16 is input to the encoding unit 20 in a state of being included in the transmission data.

  When the demodulated signal is input to the decoding unit 14, the demodulated signal is decoded by the decoding unit 14 and output to the downlink SINR report value extraction unit 15. Then, the downlink SINR report value included in the decoded signal is extracted. The downlink SINR report value extracted by the downlink SINR report value extraction unit 15 is output to the output control unit 19, and the downlink SINR value stored in the output control unit 19 is updated (step S37).

  The detection result of the Doppler frequency detection unit 17 is output to the target SINR value determination unit 18. The target SINR value determination unit 18 determines a target SINR value based on the detection result. For example, as described with reference to FIG. 4, when the Doppler frequency detected by the Doppler frequency detector 17 is low, the target SINR value is set to T1, and when the Doppler frequency detected by the Doppler frequency detector 17 is high. Sets the target SINR value to T2, which is lower than T1. The target SINR value determined by the target SINR value determination unit 18 is output to the output control unit 19.

  The output control unit 19 transmits so that the signal quality of the radio signal to be transmitted (that is, the radio signal received by the mobile station 6) becomes the signal quality indicated by the target SINR value determined by the target SINR value determination unit 18. Control the output of radio signals. Specifically, the difference between the input target SINR value and the downlink SINR report value extracted by the downlink SINR report value extraction unit 15 is obtained, and the output increase / decrease amount of the radio signal to be transmitted is obtained from this difference to obtain the target output. And control so that the output of the radio signal to be transmitted becomes the determined target output. Here, the output control unit 19 controls the output of the radio signal by performing control for changing the modulation method in the modulation unit 21 or performing control for changing the gain of the radio transmission unit 22 (step S38). When the above processing is completed, transmission data including an uplink SINR value is transmitted from the base station 5 to the mobile station 6 (step S39).

  As described above, in the present embodiment, the base station 5 calculates the uplink SINR value, the mobile station 6 calculates the downlink SINR value, and transmits these to the communication partner to report the calculated value. . While making such a report, in the present embodiment, the target SINR value is determined according to the Doppler frequency detected by the Doppler frequency detection unit 17 of the base station 5, and the base station 5 uses the determined target SINR value. The target SINR value is determined according to the Doppler frequency detected by the mobile station 6 Doppler frequency detection unit 41, and the mobile station 6 is used using the determined target SINR value. The transmission output of the radio signal from is controlled. For this reason, also in this embodiment, power consumption can be suppressed and an increase in noise (interfering radio waves) can be prevented.

  As described above, the wireless communication system, the wireless communication terminal device, the relay device, and the wireless communication method according to the embodiment of the present invention have been described. However, the present invention is not limited to the above-described embodiment, and is freely within the scope of the present invention. It can be changed. For example, in the above-described embodiment, the case where the Doppler frequency is detected has been described as an example. The present invention can also be applied to the case where fading caused by the phase change is detected.

  In the above embodiment, the Doppler frequency generated by the movement of the mobile station is detected. For example, the mobile station is provided with a GPS (Global Positioning System) function, and using this function, the moving speed information of the mobile station is obtained. The target SINR value may be determined from the obtained moving speed information. Further, in the above embodiment, the SINR value is used as the quality information indicating the quality of the radio signal. However, in addition to this, a CNR (Carrier to Noise Ratio) value, an SNR (Signal to Noise Ratio: A signal to noise ratio (CIR) value, a CIR (Carrier to Interference Ratio) value, or a SIR (Signal to Interference Ratio) value can also be used.

It is a block diagram which shows the structure of the radio | wireless communications system by the 1st Embodiment of this invention, a radio | wireless communication terminal device, and a relay apparatus. It is a figure which shows the relationship between the transmission side SINR value and the receiving side SINR side. It is a figure for demonstrating the detection method of the Doppler frequency using the normalization inner product value. It is a figure which shows an example of the relationship between the Doppler frequency and the target SINR value determined. 5 is a timing chart for explaining operations of the wireless communication system, the wireless communication terminal device, and the relay device according to the first embodiment of the present invention. It is a block diagram which shows the structure of the radio | wireless communications system by the 2nd Embodiment of this invention, a radio | wireless communication terminal device, and a relay apparatus. It is a timing chart for demonstrating operation | movement of the radio | wireless communications system by the 2nd Embodiment of this invention, a radio | wireless communication terminal device, and a relay apparatus. It is a block diagram which shows the structure of the radio | wireless communications system by the 3rd Embodiment of this invention, a radio | wireless communication terminal device, and a relay apparatus. It is a timing chart for demonstrating operation | movement of the radio | wireless communications system by the 3rd Embodiment of this invention, a radio | wireless communication terminal device, and a relay apparatus.

Explanation of symbols

1 Base station 2 Mobile station (wireless communication terminal device)
3 Base station 4 Mobile station (wireless communication terminal equipment)
5 Base station 6 Mobile station (wireless communication terminal equipment)
15 Downlink SINR report value extraction unit (extraction unit)
16 Uplink SINR value calculation unit (quality information calculation unit)
17 Doppler frequency detector (variation detector)
18 Target SINR value determination unit (target signal quality determination unit)
19 Output control unit 22 Wireless transmission unit (transmission unit)
35 Downlink SINR value calculation unit (quality information calculation unit)
39 Wireless transmitter (transmitter)
40 Uplink SINR report value extraction unit (extraction unit)
41 Doppler frequency detector (variation detector)
42 Target SINR value determination unit (target signal quality determination unit)
43 Output controller

Claims (11)

In a wireless communication system that performs wireless communication between a base station and a wireless communication terminal device,
At least one of the base station and the wireless communication terminal device,
A fluctuation detector for detecting characteristic fluctuations due to disturbance of the radio signal;
A target signal quality determination unit that determines a target signal quality of a radio signal based on a detection result of the fluctuation detection unit;
An output control unit for controlling the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the target signal quality ;
Equipped with a,
When the first value indicating the characteristic variation is larger than the second value, the target signal quality is set so that the target signal quality set to the first value is set to the second value. A wireless communication system, wherein the wireless communication system is set to be lower .   The output control unit determines a target output of a radio signal to be transmitted based on a difference between the target signal quality determined by the target signal quality determination unit and quality information indicating the quality of the radio signal, and transmits the radio signal The wireless communication system according to claim 1, wherein the output is controlled to be the target output.   The wireless communication system according to claim 1, wherein the fluctuation detection unit detects a Doppler frequency of the radio signal as a characteristic fluctuation of the radio signal.   The wireless communication system according to claim 1, wherein the fluctuation detection unit detects fading of the radio signal as a characteristic fluctuation of the radio signal.   The said base station and the said radio | wireless communication terminal apparatus are provided with the quality information calculation part which calculates the said quality information from the said received radio signal, The Claim 1 characterized by the above-mentioned. Wireless communication system.   6. The radio communication system according to claim 5, wherein each of the base station and the radio communication terminal device includes a transmission unit that transmits the quality information calculated by the quality information calculation unit to a partner side.   The wireless communication system according to claim 5, wherein the base station and the wireless communication terminal device include an extraction unit that extracts the quality information transmitted from a counterpart.   The fluctuation detecting unit includes a moving speed detecting unit that detects a moving speed of the wireless communication terminal device, and determines the target signal quality according to the moving speed detected by the moving speed detecting unit. The wireless communication system according to any one of claims 1 to 7. In a wireless communication terminal device that performs wireless communication with a base station,
A fluctuation detector for detecting characteristic fluctuations due to disturbance of the radio signal;
A target signal quality determination unit that determines a target signal quality of a radio signal based on a detection result of the fluctuation detection unit;
An output control unit for controlling the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the target signal quality ;
Equipped with a,
When the first value indicating the characteristic variation is larger than the second value, the target signal quality is set so that the target signal quality set to the first value is set to the second value. A wireless communication terminal device , which is set to be lower . In a relay device that performs wireless communication with a wireless communication terminal device,
A fluctuation detector for detecting characteristic fluctuations due to disturbance of the radio signal;
A target signal quality determination unit that determines a target signal quality of a radio signal based on a detection result of the fluctuation detection unit;
An output control unit for controlling the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the target signal quality ;
Equipped with a,
When the first value indicating the characteristic variation is larger than the second value, the target signal quality is set so that the target signal quality set to the first value is set to the second value. A relay device characterized by being set to be lower . A wireless communication method used in a wireless communication system for performing wireless communication between a base station and a wireless communication terminal device,
A first step of detecting characteristic variation due to disturbance of the radio signal;
A second step of determining a target signal quality of the radio signal based on the detection result of the first step;
A third step of controlling the output of the radio signal to be transmitted so that the signal quality of the radio signal becomes the target signal quality ;
Only including,
When the first value indicating the characteristic variation is larger than the second value, the target signal quality is set so that the target signal quality set to the first value is set to the second value. A wireless communication method characterized by being set to be lower .

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