JP2011249998A - Radio communication terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent deterioration in reception characteristics caused by interference waves.SOLUTION: A terminal includes communication means that detect an interference wave from a reception signal, subtract a frequency of a subcarrier having a desired wave from the frequency of the interference wave, determine a remainder (offset frequency) obtained by dividing the subtraction result by a subcarrier frequency interval, and change the setting of a reception frequency based on the offset frequency.

Description

  The present invention relates to a wireless communication terminal.

  At present, communication systems using LTE (Long Term Evolution) based on OFDM (Orthogonal Frequency Division Multiplexing), WiMAX (Worldwide Interoperability for Microwave Access), and the like have appeared. In these communication systems, a low-power microcell base station is arranged between cells that cannot be covered by a high-power macrocell base station as a base station placement form.

  However, when a terminal exists at the edge of a cell of the macro cell base station, the terminal transmits a high level of power to the macro cell base station, so that the radio wave of the terminal becomes an interference wave, and the cell of the micro cell base station The downlink performance (reception characteristics) of the terminal inside is degraded. For example, the frequency deviation (Doppler shift) in the OFDM signal output by the terminal when the terminal in the cell of the macro cell base station moves at high speed (or the radio wave in fixed communication is reflected by an object moving at high speed) ) Occurs, the OFDM signal becomes an interference wave and degrades the reception characteristics of the terminals in the cell of the microcell base station. In particular, when the frequency of the desired wave subcarrier is subtracted from the frequency of the interference wave, and the remainder (offset frequency) obtained by dividing the calculation result by the frequency interval of the subcarrier is ½ times the subcarrier frequency interval. Then, the interference wave and the subcarrier are correlated and the reception characteristic is most deteriorated (for example, see FIG. 5A).

  Therefore, in order to solve such a problem, in Patent Document 1 below, a mobile station's moving speed, latitude, and longitude are calculated using a GPS satellite, and the mobile station is calculated based on the moving speed, latitude, and longitude. And the base station, the Doppler shift amount of the transmission wave from the mobile station is calculated from the angle, and the transmission wave of the mobile station is finely adjusted based on the calculation result. A mobile communication system for correcting the above is disclosed.

JP 2001-119333 A

  By the way, in the above prior art, by correcting the Doppler shift, it is possible to suppress the occurrence of interference waves due to the Doppler shift, but the cause of the interference waves is not only the Doppler shift but there are various causes. When an interference wave is generated due to a cause other than the Doppler shift, it is not possible to suppress the deterioration of reception characteristics due to the interference wave.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to suppress deterioration of reception characteristics due to interference waves.

  In order to achieve the above object, according to the present invention, as a first solution for a radio communication terminal, a terminal that receives a radio signal based on a multicarrier communication scheme using a plurality of subcarriers, When there is an interference wave, the frequency of the desired wave subcarrier is subtracted from the frequency of the interference wave, and a remainder (offset frequency) obtained by dividing the calculation result by the frequency interval of the subcarrier is calculated. Based on the offset frequency A means for providing a communication means for changing the reception frequency setting is employed.

  In the present invention, as a second solving means relating to a wireless communication terminal, in the first solving means, a terminal that receives a radio signal from a base station, the communication means calculates the offset frequency, A means for changing a reception frequency setting based on the offset frequency and transmitting an instruction to the base station to change a transmission frequency based on the offset frequency is adopted.

  In the present invention, as a third solving means relating to a wireless communication terminal, in the first or second solving means, the communication means, when an error rate of a received signal exceeds a predetermined threshold value, A means for detecting an interference wave of the received signal and calculating the offset frequency when an interference wave exists in the received signal is employed.

  In the present invention, as a fourth solving means relating to the radio communication terminal, a means is adopted in which the error rate is a FER (Frame Error Rate) in the third solving means.

  According to the present invention, when there is an interference wave in the received signal, the communication means subtracts the frequency of the desired wave subcarrier from the frequency of the interference wave, and divides the calculation result by the frequency interval of the subcarrier ( Offset frequency) is calculated, and the reception frequency setting is changed based on the offset frequency. Thus, by changing the reception frequency setting based on the offset frequency, a signal that is uncorrelated with the interference wave can be received. it can.

It is a system configuration figure showing radio communications system S provided with terminal A concerning an embodiment of the present invention. It is a functional block diagram of the terminal A which concerns on embodiment of this invention. 2 is a functional block diagram of a microcell base station C. FIG. It is a flowchart which shows operation | movement of the terminal A which concerns on embodiment of this invention. It is a figure which shows the change of a receiving frequency setting based on the offset frequency of the terminal A which concerns on embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
The wireless communication system S is a communication system employing an OFDM (Orthogonal Frequency Division Multiplexing) scheme, and as shown in FIG. 1, terminals (wireless communication terminals) A and B, a microcell base station C, and It consists of a macrocell base station D.

The terminal A is located in the cell CL1 of the microcell base station C, communicates with the microcell base station C, and performs voice communication or data communication.
The terminal B is located in the cell CL2 of the macro cell base station D and communicates with the macro cell base station D to perform voice communication or data communication.

The microcell base station C is a low-power base station that covers a gap between cells of the high-power macrocell base station D and other macrocell base stations (not shown), forms the cell CL1, and is located in the cell CL1. It communicates with the terminal A which carries out by the OFDM system.
The macrocell base station D is a high-power base station, forms a cell CL2, and communicates with a terminal B located in the cell CL2 by the OFDM method.

Next, the functional configuration of the terminal A will be described with reference to FIG.
The terminal A includes a receiving unit 1, a transmitting unit 2, and a control unit 3. The reception unit 1, the transmission unit 2, and the control unit 3 constitute communication means in the present embodiment.
The receiving unit 1 includes an antenna 1a, an amplifier 1b, a mixer 1c, a frequency adjusting unit 1d, an A / D converter 1e, and an OFDM demodulation processing unit 1f.

The antenna 1a outputs the received reception signal to the amplifier 1b.
The amplifier 1b amplifies the reception signal input from the antenna 1a and outputs it to the mixer 1c.
The mixer 1c mixes the received signal input from the amplifier 1b with the local signal input from the frequency adjusting unit 1d, thereby frequency-converting (down-converting) the received signal into an IF received signal having an IF frequency. The IF reception signal is output to the A / D converter 1e.

The frequency adjusting unit 1d generates a local signal for IF frequency conversion and outputs the local signal to the mixer 1c. The reference pulse oscillator 1d-1, the counter 1d-2, the phase comparator 1d-3, and the loop filter 1d-4 And a local signal oscillator 1d-5.
The reference pulse oscillator 1d-1 is composed of a crystal oscillator or a ceramic oscillator, generates a reference pulse signal based on the periodic vibration of the oscillator, and outputs the reference pulse signal to the phase comparator 1d-3.
The counter 1d-2 divides the local signal input from the local signal oscillator 1d-5 based on the frequency division ratio set in the register by the control unit 3, and the divided pulse signal is used as the phase comparator 1d-. 3 is output.

The phase comparator 1d-3 generates a phase difference pulse signal based on the phase difference between the reference pulse signal input from the reference pulse oscillator 1d-1 and the pulse signal input from the counter 1d-2. The phase difference pulse signal is output to the loop filter 1d-4.
The loop filter 1d-4 outputs a voltage signal obtained by integrating the phase difference pulse signal input from the phase comparator 1d-3 to the local signal oscillator 1d-5.
The local signal oscillator 1d-5 generates a local signal for IF frequency conversion having a frequency based on the voltage signal input from the loop filter 1d-4, and outputs the local signal to the mixer 1c.

The A / D converter 1e digitally converts the IF reception signal input from the mixer 1c and outputs the digital IF reception signal to the OFDM demodulation processing unit 1f as a digital IF reception signal.
The OFDM demodulation processing unit 1f performs demodulation processing based on the OFDM method such as Fourier transform processing, digital demodulation processing, parallel-serial conversion processing, etc., on the digital IF reception signal input from the A / D converter 1e as a baseband reception signal Output to the control unit 3. The OFDM demodulation processing unit 1 f detects an interference wave included in the digital IF reception signal during the Fourier transform process, and notifies the control unit 3 of the frequency of the interference wave. Further, the OFDM demodulation processing unit 1 f detects the FER (Frame Error Rate) of the received signal based on the digital IF received signal, and notifies the control unit 3 of the FER.

The transmission unit 2 includes a transmission circuit unit 2a and an antenna 2b.
The transmission circuit unit 2a modulates the baseband transmission signal input from the control unit 3 and outputs it to the antenna 2b as a transmission signal.
The antenna 2b transmits the transmission signal input from the transmission circuit unit 2a to the outside.
The control unit 3 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an interface circuit for inputting / outputting signals to / from each unit, and the like, which are stored in the ROM. The overall operation of the terminal A is controlled based on the control program and the received signal received by the receiving unit 1. The control program stored in the ROM includes a terminal interference suppression program, and the control unit 3 suppresses deterioration of reception characteristics due to interference waves based on the terminal interference suppression program.

Next, the functional configuration of the microcell base station C will be described with reference to FIG.
The microcell base station C includes a receiving unit 11, a transmitting unit 12, and a control unit 13.
The receiving unit 11 includes an antenna 11a and a receiving circuit unit 11b.
The antenna 11a outputs the received reception signal to the reception circuit unit 11b.
The receiving circuit unit 11b demodulates the received signal under the control of the control unit 13, and outputs the demodulated signal to the control unit 13 as a baseband received signal.

The transmission unit 12 includes an OFDM modulation processing unit 12a, a D / A converter 12b, a mixer 12c, a frequency adjustment unit 12d, an amplifier 12e, and an antenna 12f.
The OFDM modulation processing unit 12a performs modulation processing based on the OFDM method such as serial-parallel conversion processing, digital modulation processing, and inverse Fourier transform processing on the baseband transmission signal input from the control unit 13, and outputs D as a digital IF transmission signal. / A output to the converter 12b.

The D / A converter 12b converts the digital IF transmission signal input from the mixer 12c into an analog signal and outputs the analog IF transmission signal to the mixer 12c.
The mixer 12c mixes the IF transmission signal input from the D / A converter 12b and the local signal input from the frequency adjustment unit 1d, thereby converting the IF transmission signal to an RF frequency transmission signal (up-conversion). And the transmission signal is output to the amplifier 12e.

The frequency adjusting unit 12d generates a local signal for RF frequency conversion and outputs the local signal to the mixer 12c. The frequency adjusting unit 12d outputs a reference pulse oscillator 12d-1, a counter 12d-2, a phase comparator 12d-3, and a loop filter 12d-4. And a local signal oscillator 12d-5.
The reference pulse oscillator 12d-1 is composed of a crystal resonator or a ceramic resonator, generates a reference pulse signal based on the periodic vibration of the resonator, and outputs the reference pulse signal to the phase comparator 12d-3.
The counter 12d-2 divides the local signal input from the local signal oscillator 12d-5 based on the division ratio set in the register by the control unit 13, and the divided pulse signal is used as the phase comparator 12d-. 3 is output.

The phase comparator 12d-3 generates a phase difference pulse signal based on the phase difference between the reference pulse signal input from the reference pulse oscillator 12d-1 and the pulse signal input from the counter 12d-2. The phase difference pulse signal is output to the loop filter 12d-4.
The loop filter 12d-4 outputs a voltage signal obtained by integrating the phase difference pulse signal input from the phase comparator 12d-3 to the local signal oscillator 12d-5.
The local signal oscillator 12d-5 generates an RF frequency conversion local signal having a frequency based on the voltage signal input from the loop filter 12d-4, and outputs the local signal to the mixer 12c.

The amplifier 12e amplifies the transmission signal input from the mixer 12c and outputs it to the antenna 12f.
The antenna 12f transmits the transmission signal input from the amplifier 12e to the outside.
The control unit 13 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an interface circuit for inputting / outputting signals to / from each unit, and the like, which are stored in the ROM. The overall operation of the microcell base station C is controlled based on the control program and the received signal received by the receiving unit 11. Note that the control program stored in the ROM includes a base station interference suppression program, and the control unit 13 suppresses degradation of the reception characteristics of the terminal A due to interference waves based on the base station interference suppression program. To do.

Next, the operation of the terminal A according to the present embodiment having the above configuration will be described with reference to FIG.
First, when the receiving unit 1 receives the received signal from the microcell base station C, the control unit 3 of the terminal A causes the OFDM demodulation processing unit 1f to detect the FER of the received signal, and based on the notification from the OFDM demodulation processing unit 1f. Then, it is determined whether or not the FER of the received signal exceeds a predetermined threshold value (step S1).
If it is determined “NO” in step S1, that is, if the FER does not exceed a predetermined threshold value, the control unit 3 stands by in step S1. If it is determined “YES” in step S1, that is, if the FER exceeds a predetermined threshold value, the control unit 3 causes the OFDM demodulation processing unit 1f to detect an interference wave, and the OFDM demodulation processing unit 1f. Whether or not an interference wave exists is determined based on the notification (step S2).

If it is determined as “NO” in step S2, that is, if there is no interference wave in the received signal, the control unit 3 prompts the macro cell base station D to perform handover (step S3). When it is determined “YES” in step S2, that is, when there is an interference wave in the received signal, the control unit 3 subtracts the frequency (center frequency) of the desired wave subcarrier from the frequency of the interference wave, The remainder (offset frequency) obtained by dividing the calculation result by the subcarrier frequency interval is calculated (step S4).
That is, the offset frequency Δf_a is calculated based on the following equation (1).
Offset frequency Δf_a = | interference wave frequency f_a−desired wave subcarrier interference wave frequency f_c | mod subcarrier frequency interval fs (1)

  For example, as shown in FIG. 5A, when the subcarrier frequency interval is 15 kHz, the value obtained by subtracting the frequency of the desired wave subcarrier from the frequency of the interference wave in step S4 is divided by 15 kHz, and the remainder 7.5 kHz is the offset frequency. In addition, when the offset frequency (7.5 kHz) is ½ times the subcarrier frequency interval (15 kHz), the reception characteristics are most deteriorated.

  Returning to FIG. 4, after step S4, the control unit 3 changes the reception frequency setting of the reception unit 1 based on the offset frequency (step S5). For example, when the offset frequency is 7.5 kHz as shown in FIG. 5A, the subcarrier reception frequency setting is shifted by 7.5 Hz as shown in FIG. 5B, that is, the subcarrier reception frequency. Increase the setting by 7.5 kHz. The control unit 3 changes the reception frequency setting by changing the register setting of the counter 1d-2.

  Returning to FIG. 4, after step S5, the control unit 3 causes the transmission unit 2 to transmit an instruction to the microcell base station C to change the transmission frequency based on the offset frequency (step S6). When the receiving unit 11 receives the instruction from the terminal A, the control unit 13 of the microcell base station C changes the transmission frequency of the transmitting unit 12 based on the offset frequency. For example, when the offset frequency is 7.5 kHz as shown in FIG. 5A, the subcarrier transmission frequency is shifted by 7.5 Hz, that is, the subcarrier transmission frequency is 7 as shown in FIG. Increase the frequency by 5 kHz. The control unit 13 changes the transmission frequency by changing the register setting of the counter 12d-2.

  Returning to FIG. 4, after step S6, the control unit 3 determines whether or not the FER of the received signal exceeds a predetermined threshold value based on the notification from the OFDM demodulation processing unit 1f (step S7). If it is determined as “YES” in step S7, that is, if the FER of the received signal exceeds a predetermined threshold, the control unit 3 determines that the received signal is not improved in step S3. Is handed over. When it is determined “NO” in step S7, that is, when the FER of the received signal does not exceed the predetermined threshold, the control unit 3 maintains the communication state with the microcell base station C as it is. (Step S8).

  As described above, in the terminal A according to the present embodiment, the OFDM demodulation processing unit 1f detects the interference wave from the digital IF reception signal, and the control unit 3 subtracts the frequency of the desired wave subcarrier from the frequency of the interference wave, The remainder (offset frequency) obtained by dividing the calculation result by the subcarrier frequency interval is calculated, and the reception frequency setting of the reception unit 1 is changed based on the offset frequency. Thereby, by changing the reception frequency setting based on the offset frequency, for example, even if a frequency deviation (Doppler shift) occurs in the transmission signal due to the high-speed movement of the terminal B and the interference wave with respect to the terminal A becomes an interference wave, Since a signal that is uncorrelated with the wave can be received, it is possible to suppress degradation of reception characteristics due to the interference wave by demodulating the signal. Further, in the terminal A, since the calculation process is only the calculation of the offset frequency, the process is simple and the development cost can be suppressed.

As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, For example, the following modifications can be considered.
(1) In the embodiment of the present invention, the reception frequency setting is increased by the offset frequency, but the present invention is not limited to this. The reception frequency setting may be lowered by the value obtained by subtracting the offset frequency from the subcarrier frequency interval.

(2) In the embodiment of the present invention, the error rate of the received signal is determined based on FER, but the present invention is not limited to this.
For example, the error rate of the received signal may be determined based on BER (Bit Error Rate), and step S2 may be executed when the BER exceeds a predetermined threshold.

DESCRIPTION OF SYMBOLS S ... Wireless communication system, A, B ... Terminal, C ... Micro cell base station, D ... Macro cell base station, CL1, CL2 ... Cell, 1 ... Receiver, 1a ... Antenna, 1b ... Amplifier, 1c ... Mixer, 1d ... Frequency adjustment unit, 1d-1 ... reference frequency oscillator, 1d-2 ... counter, 1d-3 ... phase comparator, 1d-4 ... loop filter, 1d-5 ... local signal oscillator, 1e ... A / D converter, 1f ... OFDM demodulation processing unit, 2 ... transmission unit, 2a ... transmission circuit unit, 2b ... antenna, 3 ... control unit, 11 ... reception unit, 11a ... antenna, 11b ... reception circuit unit, 12 ... transmission unit,
12a ... OFDM modulation processing unit, 12b ... D / A converter, 12c ... mixer, 12d ... frequency adjustment unit, 12d-1 ... reference frequency oscillator, 12d-2 ... counter, 12d-3 ... phase comparator, 12d-4 ... Loop filter, 12d-5 ... Local signal oscillator, 12e ... Amplifier, 12f ... Antenna, 13 ... Control part

Claims (4)

A terminal that receives a radio signal based on a multicarrier communication scheme using a plurality of subcarriers,
If there is an interference wave in the received signal, the frequency of the desired wave subcarrier is subtracted from the frequency of the interference wave, and the remainder (offset frequency) obtained by dividing the calculation result by the frequency interval of the subcarrier is calculated. A wireless communication terminal comprising communication means for changing the reception frequency setting based on the above. A terminal that receives a radio signal from a base station,
The communication means calculates the offset frequency, changes a reception frequency setting based on the offset frequency, and transmits an instruction to the base station to change a transmission frequency based on the offset frequency. The wireless communication terminal according to claim 1.   The communication means detects an interference wave of the reception signal when an error rate of the reception signal exceeds a predetermined threshold, and calculates the offset frequency when the interference signal exists in the reception signal. The wireless communication terminal according to claim 1, wherein the wireless communication terminal is a wireless communication terminal. The wireless communication terminal according to claim 3, wherein the error rate is a FER (Frame Error Rate).

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