JP6584120B2 - Wireless communication device - Google Patents

Description

The present invention relates to a technology of a MIMO-OFDM (Multiple Input Multiple Output-Orthogonal Frequency Division Multiplexing) system that performs one-to-one bidirectional communication using a time division duplex (TDD) method, and in particular, a plurality of independent. match the radio frequency signal outputted from the transmitting and receiving radio-frequency unit which is about the wireless communication equipment.

  Conventionally, in a MIMO-OFDM system, it is necessary to acquire accurate channel information on the transmission side in order to realize high-efficiency transmission using precoding. As a method of acquiring channel information on the transmission side, a method of feeding back channel information acquired on the reception side to the transmission side is generally used.

  In the TDD radio communication system, the same radio channel is used for the uplink and the downlink, so that channel information is not fed back and the reciprocity of the channel is used to transmit the uplink to the downlink or the uplink to the downlink. Estimate the channel of the line. As a result, it is theoretically possible to acquire the channel information with high accuracy and high speed, and there are significant advantages such as no reduction in transmission efficiency due to feedback.

  However, in reality, there is an individual difference between the wireless communication device on the transmission side and the wireless communication device on the reception side, and there is a reciprocity theorem in the entire system including the wireless communication device on the transmission side and the wireless communication device on the reception side. It doesn't hold true. For this reason, it is essential to establish a calibration technique that eliminates the influence of individual differences.

  Furthermore, in the transmission / reception high-frequency unit provided in each of the transmission-side radio communication device and the reception-side radio communication device in addition to the uplink and downlink, if there is a frequency deviation due to the individual difference of the local oscillator, High-accuracy channel estimation on the transmission side using reciprocity becomes more difficult.

  As a method of synchronizing the frequency of each local oscillator between a transmitting-side radio communication device and a receiving-side radio communication device, for example, a method using a GPS (Global Positioning System) satellite signal as a reference signal is proposed. (For example, see Patent Document 1, Patent Document 2, and Patent Document 3).

  In addition to a method of using a GPS satellite signal, a method of synchronizing a frequency by distributing a reference signal via a wired network is also known.

JP 2011-103600 A Japanese Patent No. 3474189 Japanese Patent No. 4550342

  However, the method of using a GPS satellite signal as a reference signal has a problem that the frequency cannot be synchronized with high accuracy in a place where the number of visible satellites is insufficient due to the influence of a building or the indoor radio station.

  In addition, the method of using a GPS satellite signal as a reference signal and the method of distributing a reference signal via a wired network require an environment in which the reference signal can be received, and each radio station has a function of receiving the reference signal. There is a problem that restrictions on operations or functions of the apparatus increase, such as needing to be mounted separately.

Therefore, the present invention has been made to solve such a problem, and the object of the present invention is to transmit and receive high-frequency signals of all wireless communication devices within a wireless communication system without using an external reference signal. to provide a wireless communication equipment capable of matching the radio frequency signal outputted from the section with high accuracy.

In order to solve the above-described problem, the radio communication apparatus on the mobile station side according to claim 1 modulates a transmission signal to transmit a radio frequency band signal (RF signal), and receives and demodulates an RF signal. A mobile station-side radio communication apparatus including a plurality of branches, and a base station-side radio communication apparatus including a plurality of branches that receive and demodulate an RF signal while transmitting a RF signal by modulating a transmission signal. The mobile station in a radio communication system based on MIMO-OFDM configured to perform one-to-one bidirectional communication between the radio communication device on the mobile station side and the radio communication device on the base station side by a time division duplex method in the radio communication apparatus side, the transceiver RF units corresponding to the plurality of branches (RF section) and the modem unit, and the mobile station-side local oscillator and the first oscillator common to the plurality of branches Wherein the mobile station-side local oscillator, and outputs a signal of the oscillation frequency of the default value, the first oscillator, and outputs a first sine-wave digital signal of the oscillation frequency of the default values, the RF unit, wherein based on the signal output by the mobile station-side local oscillator, converts the frequency of the RF signal received, and down-converter to output as a reception signal, based on the signal output by the mobile station-side local oscillator, wherein An up-converter that converts the frequency of a quadrature-modulated transmission signal from the modulation / demodulation unit and outputs it as an RF signal transmitted by the radio communication device on the mobile station side, and the modulation / demodulation unit includes the mobile station-side local oscillator detecting a deviation of the oscillation frequency between the base station-side local oscillator provided in the wireless communication apparatus of the base station side, and the frequency deviation detecting unit for outputting a frequency deviation, the first shot Inputs the first sine-wave digital signal output by the vessel, enter the average frequency deviation is the average value of the frequency deviation in the plurality of branches, the average from the oscillation frequency of the first sine-wave digital signal the frequency deviation is subtracted, a second oscillator for generating a second sine-wave digital signal for correcting the average frequency deviation, based on the second sine-wave digital signal generated by the second oscillator, the RF unit A quadrature demodulator for quadrature demodulating the received signal output by the down converter, a quadrature modulator for quadrature modulating the transmission signal based on the first sine wave digital signal output by the first oscillator, and the plurality The frequency deviations output by the frequency deviation detection unit in the modulation / demodulation unit of each branch are respectively input, and the frequency deviations of the plurality of branches are calculated. And calculating an average frequency deviation that is an average value in the plurality of branches and outputting the average frequency deviation, and using the RF signal output by the up-converter as a reference signal, the movement Each of the RFs transmitted by a plurality of branches provided in the base station side radio communication device to a fixed radio frequency of each of the RF signals transmitted by a plurality of branches provided in the station side radio communication device. The radio frequency of the signal is matched .

Further, the base station side radio communication apparatus according to claim 2 and the mobile station side radio communication apparatus according to claim 1 transmit an RF signal by modulating a transmission signal, and also from the mobile station side radio communication apparatus. A radio communication device on the base station side having a plurality of branches that receive and demodulate the transmitted RF signal, and the radio communication device on the mobile station side and the radio on the base station side by a time division duplex method In the radio communication device on the base station side in the MIMO-OFDM radio communication system that performs one-to-one bidirectional communication with the communication device, a transmission / reception high-frequency unit ( RF unit ) corresponding to each of the plurality of branches; A modulation / demodulation unit, and a base station-side local oscillator and a first oscillator common to the plurality of branches, wherein the base station-side local oscillator outputs a signal having a predetermined oscillation frequency, and the first oscillator Outputs a first sine wave digital signal having a predetermined oscillation frequency, and the RF unit converts the frequency of the received RF signal based on the signal output by the base station side local oscillator, and receives the signal. Based on the down-converter output as a signal and the signal output from the base station-side local oscillator, the frequency of the orthogonally modulated transmission signal from the modulation / demodulation unit is converted, and the base station-side radio communication apparatus transmits An up-converter that outputs as an RF signal, and the modulation / demodulation unit generates an oscillation frequency deviation between the base station-side local oscillator and a mobile station-side local oscillator provided in the mobile station-side radio communication device. detecting a frequency deviation detecting unit for outputting a frequency deviation, inputs the first sine-wave digital signal output by said first oscillator, put into the plurality of branches Enter the average frequency deviation is the average value of the frequency deviation, the said average frequency deviation from the oscillation frequency of the first sine-wave digital signal by subtracting the second sine-wave digital signal for correcting the average frequency deviation a second oscillator for generating, with the quadrature demodulating unit based on the second oscillator second sine-wave digital signal generated by the orthogonal demodulating a received signal output by the down converter of the RF section, the second Based on the second sine wave digital signal generated by the oscillator, the orthogonal modulation unit that orthogonally modulates the transmission signal, and the frequency deviation output by the frequency deviation detection unit in the modulation / demodulation unit of the plurality of branches, respectively, The average frequency deviation which is an average value in the plurality of branches is calculated from the frequency deviation of the plurality of branches, and the average frequency is calculated. With an average unit for outputting the deviation, and the radio frequency of each of the RF signals transmitted by a plurality of branches having the radio communication apparatus of the base station, with the radio communication device of the mobile station side The RF signal output by the up-converter of the RF unit is used as a reference signal to match the fixed radio frequency of each of the RF signals transmitted by a plurality of branches provided in the radio communication device on the mobile station side. Features.

The radio communication apparatus of the base station side according to claim 3, the wireless communication device of a mobile station according to claim 1, sends an RF signal by modulating the transmission signal from the wireless communication device of the mobile station side A radio communication device on the base station side having a plurality of branches that receive and demodulate the transmitted RF signal, and the radio communication device on the mobile station side and the radio on the base station side by a time division duplex method In the base station side wireless communication apparatus in a MIMO-OFDM wireless communication system that performs one-to-one bidirectional communication with a communication apparatus, a base station side local oscillator and a transmission / reception high frequency corresponding to each of the plurality of branches Unit ( RF unit ), modulation / demodulation unit , and a first oscillator common to the plurality of branches, the base station side local oscillator outputs a signal having a predetermined oscillation frequency, and the first oscillator Outputs the first sine-wave digital signal of the oscillation frequency of the default values, the RF section, front SL based on the signal output by the base station-side local oscillator, converts the frequency of the RF signal received, received Based on the down-converter output as a signal and the signal output from the base station-side local oscillator, the frequency of the orthogonally modulated transmission signal from the modulation / demodulation unit is converted, and the base station-side radio communication apparatus transmits includes an up converter for output as RF signals, a to the deviation of the oscillation frequency between the modulation and demodulation unit, a mobile station-side local oscillator provided in the wireless communication device prior SL base station-side local oscillator and the mobile station side detects a frequency deviation detecting unit for outputting a frequency deviation, inputs the first sine-wave digital signal output by said first oscillator by the frequency deviation detecting unit A second oscillator type the force frequency deviation, the said frequency deviation is subtracted from the oscillation frequency of the first sine-wave digital signal, for generating a second sine-wave digital signal for correcting the frequency deviation, based on the second sine-wave digital signal generated by said second oscillator, a quadrature demodulator for quadrature demodulating the received signal outputted by the down converter of the RF section, the second sine generated by the second oscillator An orthogonal modulation unit that orthogonally modulates the transmission signal based on a wave digital signal, and the radio frequency of each of the RF signals transmitted by a plurality of branches provided in the radio communication device on the base station side, The RF signal output from the up-converter of the RF unit provided in the mobile station side radio communication device is used as a reference signal, and is provided in the mobile station side radio communication device. To match the fixed radio frequencies of the RF signals transmitted by a plurality of branches, characterized in that.

According to a fourth aspect of the present invention, in the wireless communication apparatus according to any one of the first to third aspects, the other wireless communication apparatus detects a frequency deviation by the time division duplex method. A fast Fourier transform operation unit that transmits and receives an RF signal of a subframe including a preamble for generating a frequency domain signal by performing fast Fourier transform on the received signal demodulated orthogonally by the orthogonal demodulator And a first frequency deviation detector that detects a first frequency deviation using a preamble included in a subframe of the received signal that has been orthogonally demodulated by the orthogonal demodulator, and the fast Fourier transform calculator. A pilot carrier extracting unit that extracts a pilot carrier from a signal in a frequency domain, and a pilot extracted by the pilot carrier extracting unit. A second frequency deviation detector that detects a second frequency deviation using a carrier, a first frequency deviation detected by the first frequency deviation detector, and a second frequency deviation detector And an adding unit that adds the detected second frequency deviation and outputs the addition result as the frequency deviation.

  As described above, according to the present invention, the radio frequencies of the signals output from the transmission and reception high-frequency units of all the radio communication devices are matched with high accuracy in the radio communication system without using an external reference signal. It becomes possible to make it.

It is the schematic which shows an example of the whole structure of the radio | wireless communications system with which embodiment of this invention is applied. 1 is a block diagram illustrating an overall configuration of a wireless communication system according to a first embodiment. It is a block diagram which shows the structure of MS1-1 of Example 1. FIG. It is a block diagram which shows the structure of BS2-1 of Example 1. FIG. 6 is a flowchart illustrating a process of correcting and matching radio frequency deviations in the first embodiment. It is a figure explaining the radio frequency of the process shown in FIG. It is a block diagram which shows the whole structure of the radio | wireless communications system of Example 2. FIG. It is a block diagram which shows the structure of BS2-2 of Example 2. FIG. In Example 2, it is a flowchart which shows the process which correct | amends and correct | amends the deviation of a radio frequency. It is a figure explaining the radio frequency of the process shown in FIG. FIG. 6 is a block diagram illustrating an overall configuration of a wireless communication system according to a third embodiment. It is a block diagram which shows the structure of MS1-3 of Example 3. FIG. In Example 3, it is a flowchart which shows the process which correct | amends and correct | amends the deviation of a radio frequency. It is a figure explaining the radio frequency of the process shown in FIG. It is a block diagram which shows the structure of MS1-4 of Example 4. It is a block diagram which shows the structure of BS2-4 of Example 4. FIG. In Example 4, it is a flowchart which shows the process which correct | amends and matches the deviation of a radio frequency.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
[Wireless communication system]
FIG. 1 is a schematic diagram illustrating an example of the overall configuration of a wireless communication system to which an embodiment of the present invention is applied. This wireless communication system includes a mobile station (MS) 110 having a plurality of antennas 111 for a mobile station, a plurality of antennas 201-1 to 201-6 for a base station, a plurality of transmission and reception high-frequency units (RF (Radio Frequency). : Radio frequency) unit) 202-1 to 202-6 and a base station (BS) 200 including a modem unit 203. MS 110 and BS 200 are wireless communication devices. The same applies to MS1-1 etc. and BS2-1 etc. described later. In the BS 200, the RF units 202-1 to 202-6 and the modem unit 203 include an E / O (electrical / optical converting unit), optical fibers 204-1 to 204-6, and an O / E (optical / electrical converting unit). Connected through.

  In this wireless communication system, the BS 200 receives radio waves transmitted from the plurality of antennas 111 installed in the MS 110 by using the plurality of antennas 201-1 to 201-6 on the BS 200 side installed on the rooftop of the building. . Then, the plurality of RF units 202-1 to 202-6 on the BS 200 side frequency-converts the radio frequency (RF) band of the received radio wave into an intermediate frequency (IF) band, and then converts the received signal into the optical fiber 204. The data is transmitted to the modem unit 203 via -1 to 204-6. On the other hand, the modem unit 203 of the BS 200 transmits the transmission signal to the MS 110 via the antennas 201-1 to 201-6 following the same path in the reverse direction.

  The MS 110 and the BS 200 perform two-way communication based on a TDD scheme in which the same radio frequency (RF) is divided and shared in the time domain. A line from the MS 110 to the BS 200 is an uplink (UL), and a line from the BS 200 to the MS 110 is a downlink (DL).

  As shown in FIG. 1, when a plurality of antennas 201-1 to 201-6 on the BS 200 side are installed at locations separated from each other, an RF band signal (RF signal) and an IF band signal (IF signal) RF units 202-1 to 202-6 that perform frequency conversion between the antennas 201-1 to 201-6 are also required individually.

  In the case where an RF signal is transmitted instead of the IF signal via the optical fibers 204-1 to 204-6, the RF units 202-1 to 202-6 on the BS 200 side are installed in the same place as the modem unit 203. . In this case, the RF units 202-1 to 202-6 and the modem unit 203 are mounted in one device. Similarly, an RF unit (not shown) corresponding to a plurality of antennas 111 on the MS 110 side may be mounted on an individual device corresponding to each antenna 111, and one unit with a modem unit (not shown) on the MS 110 side. It may be implemented in the device.

  Here, the signal transmitted and received between MS 110 and BS 200 is a TDD subframe. That is, MS 110 and BS 200 transmit and receive TDD subframes to each other. Within a predetermined frame period, a subframe period in which a TDD subframe is transmitted from the MS 110 to the BS 200 and a subframe period in which a TDD subframe is transmitted from the BS 200 to the MS 110 are set in advance. The period of the subframe in which the TDD subframe is transmitted from the MS 110 to the BS 200 and the period of the subframe in which the TDD subframe is transmitted from the BS 200 to the MS 110 may be the same or different. The MS 110 transmits a TDD subframe to the BS 200 within the former subframe period, and the BS 200 transmits a TDD subframe to the MS 110 within the latter subframe period.

  The MS 110 and the BS 200 mutually transmit a TDD subframe including a preamble to the other under a TDD scheme in which transmission and reception are switched for each subframe period on the time axis to perform bidirectional communication, and a TDD including the preamble is transmitted. A subframe is received from the other. In addition, the MS 110 and the BS 200 transmit a TDD subframe that does not include a preamble to the other side, and receive a TDD subframe that does not include a preamble from the other side. The preamble is used for detecting the frame synchronization timing of the TDD subframe. Details will be described later.

[Example 1]
First, Example 1 will be described. The first embodiment uses four antennas installed in the MS and four antennas installed in the BS when each branch of the MS uses a common local oscillator and each branch of the BS also uses a common local oscillator. This is an example in which the radio frequency of the RF signal transmitted from is matched. Hereinafter, a branch indicates a processing system corresponding to each antenna.

  FIG. 2 is a block diagram illustrating the overall configuration of the wireless communication system according to the first embodiment. The wireless communication system according to the first embodiment includes an MS 1-1 including four antennas 3, an RF unit 4-1, and a modem unit 5-1, four antennas 6, an RF unit 7-1, and a modem unit 8-. 1 and BS 2-1 provided with 1. This wireless communication system is a 4 × 4 MIMO-OFDM system. The same applies to Examples 2 to 4 described later.

  In the first embodiment, in each of the MS 1-1 and the BS 2-1, the RF units 4-1 and 7-1 corresponding to the four antennas 3 and 6 are mounted in one RF device, respectively. 4-1 and 7-1 are examples in which the signals of one local oscillator (mobile station side local oscillator) 40 and local oscillator (base station side local oscillator) 70 are distributed and used in common in each branch. The modulation method is assumed to be OFDM.

  In the first embodiment, there is a frequency deviation between MS1-1 and BS2-1, and there is no frequency deviation between branches in MS1-1 and BS2-1.

  The RF section 4-1 of the MS 1-1 includes one local oscillator 40, and for each branch, a switch 55, a down converter (D / C: Down Converter) 41, and an up converter (U / C: Up). Converter: frequency conversion unit) 42 is provided. The D / C 41 converts the RF signal received from the BS 2-1 via the antenna 3 and the switch 55 into an IF signal based on a sine wave signal having a predetermined frequency (oscillation frequency having a predetermined value Lo) output from the local oscillator 40. This is a module for frequency conversion. The U / C 42 is a module for converting the IF signal into an RF signal based on a sine wave signal having a predetermined frequency output from the local oscillator 40. The RF signal is transmitted to the BS 2 via the switch 55 and the antenna 3. -1.

The modulation / demodulation unit 5-1 of the MS 1-1 includes one oscillator 50, an analog / digital conversion unit (A / D conversion unit ) 51 and a digital / analog conversion unit (D / A conversion unit ) 52 for each branch, and one signal processing. A portion 53 is provided. The signal processing unit 53 includes a processing unit for each branch and one averaging unit 54, and is configured by, for example, an FPGA (Field Programmable Gate Array).

  The RF unit 7-1 of the BS 2-1 includes one local oscillator 70, and includes a switch 60, a D / C 71, and a U / C 72 for each branch. The D / C 71 converts the RF signal received from the MS 1-1 through the antenna 6 and the switch 60 into an IF signal based on a sine wave signal having a predetermined frequency (oscillation frequency of a predetermined value Lo) output from the local oscillator 70. This is a module for frequency conversion. The U / C 72 is a module for converting the IF signal into an RF signal based on a sine wave signal having a predetermined frequency output from the local oscillator 70. The RF signal is transmitted to the MS1 via the switch 60 and the antenna 6. -1.

  The modulation / demodulation unit 8-1 of the BS 2-1 includes one oscillator 80, an A / D conversion unit 81 and a D / A conversion unit 82 for each branch, and one signal processing unit 83. The signal processing unit 83 includes a processing unit for each branch and one averaging unit 84, and is configured by, for example, an FPGA.

  Since the local oscillator 40 of the RF unit 4-1 in the MS 1-1 is common to all branches, the frequency deviation between the branches is zero. The same applies to the local oscillator 70 of the RF unit 7-1 in the BS 2-1. On the other hand, the oscillation frequency of the sine wave signal output from the local oscillator 40 of the RF unit 4-1 in the MS 1-1 and the oscillation frequency of the sine wave signal output from the local oscillator 70 of the RF unit 7-1 in the BS 2-1 And there is a frequency deviation due to individual differences. Therefore, this frequency deviation (frequency deviation between MS1-1 and BS2-1) is corrected, the frequency of the RF signal transmitted from MS1-1 to BS2-1, and from BS2-1 to MS1-1. It is necessary to match the frequency of the transmitted RF signal. Hereinafter, a process of correcting the frequency deviation and matching the frequencies of the RF signals will be described.

(MS1-1 / Example 1)
First, the MS 1-1 shown in FIG. 2 will be described in detail. FIG. 3 is a block diagram showing the configuration of the MS 1-1. The MS 1-1 includes an antenna 3, a switch 55, an RF unit 4-1, and a modem unit 5-1. For the sake of explanation, the RF unit 4-1 and the modem unit 5-1 illustrated in FIG. 3 indicate the configuration of one branch among the four branches in the RF unit 4-1 and the modem unit 5-1 illustrated in FIG. ing. The switch 55 shown in FIG. 3 corresponds to the switch 55 of the RF unit 4-1 shown in FIG. 2, but is shown to be installed outside the RF unit 4-1 for the sake of explanation.

  The lower part of MS1-1 shown in FIG. 3 is a transmission processing block part, and the upper part is a reception processing block part. Specifically, the transmission processing block unit is configured by the U / C 42 of the RF unit 4-1 and the IFFT calculation unit 10,..., The QM 14 and the D / A conversion unit 52 of the modem unit 5-1. . The D / C 41 of the RF unit 4-1, the A / D conversion unit 51, the QDM 20,..., The reset signal generation unit 37, and the switch 38 of the modulation / demodulation unit 5-1, constitute a reception processing block unit.

  The switch 55 receives a switching signal from the frame synchronization detection unit 26 of the modem unit 5-1 described later, and switches the internal switch to the receiving side (the D / C 41 side of the RF unit 4-1 described later) based on the switching signal. ) Or the transmission side (the U / C 42 side of the RF unit 4-1 described later). Specifically, when the switching signal indicates a period during which the RF signal is received, the switch 55 connects the antenna 3 and the reception side, inputs the RF signal via the antenna 3, and outputs the RF signal to the reception side. On the other hand, when the switching signal indicates a period during which the RF signal is transmitted, the switch 55 connects the antenna 3 and the transmission side, inputs the RF signal from the transmission side, and transmits the RF signal via the antenna 3.

(RF section 4-1)
The RF unit 4-1 includes a D / C 41 and a U / C 42 in a one-branch configuration. The local oscillator 40 is used in common for all branches.

  The D / C 41 receives the RF signal transmitted from the BS 2-1 and received by the antenna 3 through the switch 55, and based on the sine wave signal having the oscillation frequency of the predetermined value Lo output from the local oscillator 40. The frequency of the RF signal is converted into an IF signal. Then, the D / C 41 outputs the IF signal as a reception signal to the modem unit 5-1.

  The U / C 42 receives an IF signal as a transmission signal from the modulation / demodulation unit 5-1, and is a sine wave signal having the oscillation frequency of a predetermined value Lo output from the local oscillator 40 (the same as the sine wave signal used by the D / C 41). The IF signal is frequency-converted to an RF signal based on the sine wave signal), and the RF signal is output to the switch 55. Thereby, the RF signal is transmitted via the switch 55 and the antenna 3.

(Modem 5-1)
The modem unit 5-1 includes a transmission processing unit shown in the lower stage and a reception processing unit shown in the upper stage in the configuration of one branch. The oscillator 50 and the averaging unit 54 are used in common for all branches.

  The transmission processing unit includes an inverse fast Fourier transform calculation unit (IFFT calculation unit) 10, a GI (Guard Interval) addition unit 11, an upsampling unit (US) 12, a low-pass filter unit (LPF) 13, an orthogonal modulation Unit (QM) 14 and a digital / analog conversion unit (D / A conversion unit) 52.

  The IFFT calculation unit 10 receives a modulated signal (transmission signal) after mapping from a component (not shown), performs IFFT (Inverse Fast Fourier Transform) on the frequency domain modulation signal, and generates a time domain modulation signal. Is generated. Then, IFFT calculation unit 10 outputs a time-domain modulation signal to GI addition unit 11.

  The GI addition unit 11 receives the time domain modulation signal from the IFFT calculation unit 10, adds a GI to the time domain modulation signal, and outputs the modulation signal with the GI added to the US12.

  The US 12 receives the modulation signal with the GI added from the GI adding unit 11, performs up-sampling processing on the modulation signal, and outputs the modulated signal after the up-sampling to the LPF 13.

  The LPF 13 receives the modulation signal after upsampling from US12, performs a filtering process for decreasing the component higher than the predetermined frequency and passing the component equal to or lower than the predetermined frequency with respect to the modulation signal. Output to.

The QM 14 inputs the modulated signal after filtering from the LPF 13 and also inputs a sine wave digital signal having an oscillation frequency of a predetermined value f _c from the oscillator 50 via the switch 38, and modulates based on the sine wave digital signal. Digital quadrature modulation is performed on the signal, and the transmission signal after digital quadrature modulation is output to the D / A converter 52.

  The D / A conversion unit 52 inputs a digital transmission signal after digital quadrature modulation from the QM 14, converts the digital signal into an analog signal, and converts the analog transmission signal as an IF signal to the U / C 42 of the RF unit 4-1. Output.

In this way, the RF signal (of the fixed radio frequency f ₁₎ is digitally quadrature-modulated from the MS 1-1 with the oscillation frequency of the fixed default value f _c and frequency-converted with the oscillation frequency of the fixed default value Lo. RF signal) is transmitted.

The reception processing unit includes an analog / digital conversion unit (A / D conversion unit) 51, a quadrature demodulation unit (QDM) 20, an LPF 21, a downsampling unit (DS) 22, a preamble storage unit 23, a mobile correlation unit 24, and a correlation peak detection unit. 25, frame synchronization detection unit 26, trigger signal generation unit 27, first frequency deviation detection unit 28, frequency deviation storage unit 29, addition unit 30, numerically controlled oscillator (NCO) 31, symbol synchronization detection unit 32, FFT window A timing unit 33, a fast Fourier transform operation unit (FFT operation unit) 34, a pilot carrier extraction unit 35, a second frequency deviation detection unit 36, a reset signal generation unit 37, and a switch 38 are provided. In this case, LPF 21, DS 22, preamble storage unit 23, mobile correlation unit 24, correlation peak detection unit 25, frame synchronization detection unit 26, trigger signal generation unit 27, first frequency deviation detection unit 28, frequency deviation storage unit 29, The adder 30, symbol synchronization detector 32, FFT window timing unit 33, FFT calculator 34, pilot carrier extractor 35, second frequency deviation detector 36, and reset signal generator 37 generate a frequency deviation (Δf ₁ + Δf _2). ) Is detected. The same applies to Examples 2 to 4 described later.

  The A / D conversion unit 51 receives an analog reception signal that is an IF signal from the D / C 41 of the RF unit 4-1, converts the analog signal into a digital signal, and outputs the digital reception signal to the QDM 20.

The QDM 20 receives a digital signal received from the A / D converter 51 and receives a sine wave digital signal (predetermined value (correction value) f _NCO (= f _c −Δf ′ ₁ −Δf ′ ₂ ) from the _NCO 31. A sine wave digital signal having an oscillation frequency) is input, and based on the sine wave digital signal, the received signal is subjected to digital quadrature demodulation, and the received signal after digital quadrature demodulation is output to the LPF 21.

  The LPF 21 receives the received signal after digital quadrature demodulation from the QDM 20, performs a filtering process to reduce the component higher than the predetermined frequency and pass the component below the predetermined frequency to the received signal. Output to DS22.

  The DS 22 inputs the received signal after filtering from the LPF 21, performs down-sampling processing on the received signal, and converts the down-sampled received signal into the moving correlation unit 24, the frame synchronization detection unit 26, the symbol synchronization detection unit 32, and the FFT calculation. To the unit 34.

  In the preamble storage unit 23, a digital signal (basic preamble) corresponding to a repetitive unit waveform among the preamble waveforms added to the head of the TDD subframe transmitted / received between the MS 1-1 and the BS 2-1 is stored. Signal) is stored. The basic signal of the preamble is a signal of 1/8 of the preamble signal formed by repeating the same waveform eight times, for example, and having the same eight waveforms, and is a signal in a repeating unit.

  The mobile correlation unit 24 inputs the received signal after down-sampling from the DS 22, reads out the preamble basic signal from the preamble storage unit 23, performs a mobile correlation operation between the received signal and the preamble basic signal, and performs cross-correlation. Calculate the value. When the cross-correlation is high between the received signal and the basic signal of the preamble on the time axis of the received signal, that is, at the time point of the preamble in the received signal, the cross-correlation value becomes a large value. The mobile correlation unit 24 outputs the cross-correlation value on the time axis of the received signal to the correlation peak detection unit 25.

  The correlation peak detector 25 receives the cross-correlation value on the time axis of the received signal from the mobile correlation unit 24, detects the correlation peak position (correlation peak timing) on the time axis at which the cross-correlation value peaks, A cross-correlation value at the correlation peak position is detected as a correlation peak value. The correlation peak position indicates a time position at which the cross-correlation value peaks within a predetermined time range on the time axis of the received signal. The correlation peak detection unit 25 outputs the correlation peak position to the frame synchronization detection unit 26 and outputs the correlation peak value to the first frequency deviation detection unit 28.

  The frame synchronization detection unit 26 inputs the received signal after down-sampling from the DS 22 and inputs the correlation peak position from the correlation peak detection unit 25. Based on the correlation peak position, the frame synchronization detection unit 26 detects the timing for starting the FFT processing from the beginning of the header portion, that is, the timing of frame synchronization of the received signal. When the MS 1-1 receives the RF signal of the TDD subframe including the preamble, the correlation peak position is detected by the correlation peak detection unit 25, so that the timing of frame synchronization for the TDD subframe including the preamble is detected.

  On the other hand, when the MS 1-1 receives the RF signal of the TDD subframe that does not include the preamble, that is, the frame synchronization detection unit 26 receives the down-sampled received signal from the DS 22, but receives the correlation signal from the correlation peak detection unit 25. When the peak position is not input, it is assumed that the frame synchronization timing to be detected is the same as the frame synchronization timing detected when receiving the RF signal of the TDD subframe including the preamble (based on the correlation peak position). Estimate (detect) the timing of frame synchronization. Specifically, the frame synchronization detection unit 26 receives the RF signal of the TDD subframe including the preamble twice by the MS 1-1, so that the frame synchronization detection is performed twice based on each correlation peak. Detect timing. Then, the frame synchronization detection unit 26 estimates the frame synchronization timing when the MS 1-1 receives a TDD subframe that does not include the preamble at the same time interval as the time interval of the two frame synchronization timings.

  Note that, when the MS 1-1 receives an RF signal of a TDD subframe that does not include a preamble, the frame synchronization timing may be estimated by a symbol synchronization detector 32 described later.

  The frame synchronization detection unit 26 generates a frame synchronization timing signal indicating the frame synchronization timing of the received signal, generates the frame synchronization timing signal as a trigger signal generation unit 27, a symbol synchronization detection unit 32, an FFT window timing unit 33, and a reset signal generation. To the unit 37.

  In addition, the frame synchronization detection unit 26, based on the detected timing of frame synchronization, the subframe period in which the MS 1-1 transmits the RF signal of the TDD subframe and the subframe period in which the RF signal of the TDD subframe is received. And the timing of switching between these periods is determined. For example, the frame synchronization detection unit 26 determines that the period from a predetermined time before the detected frame synchronization timing to a predetermined time later is a subframe period in which the RF signal of the TDD subframe is received. It is determined that the period is a period of a subframe in which the RF signal of the TDD subframe is transmitted.

  The frame synchronization detection unit 26 generates a switching signal for switching between transmission and reception of an RF signal (a switching signal indicating a period of a subframe in which the RF signal is transmitted or a switching signal indicating a period of a subframe in which the RF signal is received). At that timing, a switching signal is output to the switch 55.

  The trigger signal generation unit 27 receives the frame synchronization timing signal from the frame synchronization detection unit 26, and when the input frame synchronization timing signal is a frame synchronization timing signal corresponding to the first TDD subframe at the start of communication, the trigger signal And output to the frequency deviation storage unit 29. When the input frame synchronization timing signal is a frame synchronization timing signal corresponding to the second TDD subframe at the start of communication, the trigger signal generation unit 27 removes the frame synchronization timing signal and does not output the trigger signal .

  Specifically, the trigger signal generation unit 27 counts the elapsed time from the previously input frame synchronization timing signal to the currently input frame synchronization timing signal, compares the elapsed time with a predetermined time, and calculates the elapsed time. Is over a predetermined time, the trigger signal is output assuming that the input frame synchronization timing signal is the frame synchronization timing signal corresponding to the first TDD subframe at the start of communication. If the elapsed time does not exceed the predetermined time, the trigger signal generation unit 27 determines that the input frame synchronization timing signal is a frame synchronization timing signal corresponding to the second and subsequent TDD subframes at the start of communication. No signal is output. Here, the predetermined time is a time from when a TDD subframe including a preamble is first received at the start of communication until a second TDD subframe including a preamble is received.

Thus, the trigger signal is output to the frequency deviation storage unit 29 at the timing when frame synchronization is first established. The trigger signal generation unit 27 sends the trigger signal to the frequency deviation storage unit 29 at a timing later than the timing at which the first frequency deviation detection unit 28 outputs the first frequency deviation Δf ₁ to the frequency deviation storage unit 29. Shall be output.

  The symbol synchronization detection unit 32 receives the down-sampled received signal from the DS 22 and also receives the frame synchronization timing signal from the frame synchronization detection unit 26, obtains a GI correlation from the received signal, and determines the frame synchronization timing signal and the GI correlation. Based on this, the symbol synchronization timing of the received signal is detected. Then, the symbol synchronization detection unit 32 generates a symbol synchronization timing signal indicating the symbol synchronization timing of the received signal, and outputs the symbol synchronization timing signal to the FFT window timing unit 33 and the reset signal generation unit 37.

  The FFT window timing unit 33 receives the frame synchronization timing signal from the frame synchronization detection unit 26 and also receives the symbol synchronization timing signal detected by the symbol synchronization detection unit 32 based on the frame synchronization timing signal and the GI correlation. Then, the FFT window timing unit 33 corrects the frame synchronization timing signal using the symbol synchronization timing signal, and uses the corrected frame synchronization timing signal to start FFT processing from the beginning of the header portion of the received signal. Is detected. Then, the FFT window timing unit 33 generates an FFT window timing signal reflecting the timing and outputs it to the FFT operation unit 34. As a result, the frame synchronization timing signal is corrected using the symbol synchronization timing signal to become an accurate timing signal, and as a result, an FFT window timing signal with an accurate timing can be generated.

  The FFT calculation unit 34 receives the down-sampled received signal from the DS 22, and also receives the FFT window timing signal from the FFT window timing unit 33, and converts the FFT window timing signal into the time domain received signal at the timing when the FFT window timing signal is input. FFT (Fast Fourier Transform) is applied to generate a frequency domain received signal. Then, the FFT calculation unit 34 outputs the received signal in the frequency domain to the pilot carrier extraction unit 35 and a configuration unit (not shown) that performs demodulation processing of the header portion and the payload portion of the TDD subframe.

Here, QDM20, based on the sine-wave digital signal of the oscillation frequency of a predetermined value _{f NCO (= f c -Δf '} 1), when the received signal digital quadrature demodulation, FFT computation section 34, frequency-polarized A received signal after down-sampling in which the difference Δf ′ ₁ is corrected is input. When the QDM 20 digitally demodulates the received signal based on a sine wave digital signal having a predetermined value f _NCO (= f _c −Δf ′ ₁ −Δf ′ ₂ ) as an oscillation frequency, the FFT calculation unit 34 The received signal after down-sampling with the corrected frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) is input.

  The reset signal generation unit 37 receives the frame synchronization timing signal from the frame synchronization detection unit 26 and also receives the symbol synchronization timing signal from the symbol synchronization detection unit 32. Further, the reset signal generation unit 37 is provided in a stage subsequent to a C / N ratio (Carrier to Noise Ratio) calculation unit (not shown) (FFT calculation unit 34), and calculates the C / N ratio based on the received signal in the frequency domain. Part)).

  The reset signal generator 37 determines whether or not the input period of the frame synchronization timing signal is a predetermined period, determines whether or not the input period of the symbol synchronization timing signal is a predetermined period, and C / It is determined whether the N ratio is equal to or greater than a predetermined threshold value.

  The reset signal generation unit 37 determines that the input period of the frame synchronization timing signal is a predetermined period, determines that the input period of the symbol synchronization timing signal is a predetermined period, and the C / N ratio is a predetermined threshold. If it is determined that the value is greater than or equal to the value, it is determined that the communication is normal.

  On the other hand, the reset signal generation unit 37 determines that the input period of the frame synchronization timing signal is not a predetermined period, determines that the input period of the symbol synchronization timing signal is not a predetermined period, or has a predetermined C / N ratio. If it is determined that it is not greater than or equal to the threshold (less than the predetermined threshold), it is determined that the communication is abnormal (communication is interrupted), and the reset signal is detected by the frequency deviation storage unit 29 and the second frequency deviation detection. To the unit 36.

  When the input period of the frame synchronization timing signal is not a predetermined period, it indicates that frame synchronization is not established, and when the input period of the symbol synchronization timing signal is not a predetermined period, it indicates that symbol synchronization is not established. In either case, it is determined that communication is abnormal.

As a result, the reset signal is output to the frequency deviation storage unit 29, the frequency deviation Δf ₁ held in the frequency deviation storage unit 29 is reset, and a null signal is output from the frequency deviation storage unit 29 to the addition unit 30. Further, the reset signal is output to the second frequency deviation detector 36, the second frequency deviation Δf ₂ output from the second frequency deviation detector 36 is reset, and a null signal is output to the adder 30. .

The first frequency deviation detector 28 receives the correlation peak value from the correlation peak detector 25, calculates the phase rotation amount between the correlation peak positions based on the correlation peak value, and calculates the frequency deviation Δf ₁ from the phase rotation amount. Is detected. Then, the first frequency deviation detection unit 28 outputs the frequency deviation Δf ₁ to the frequency deviation storage unit 29.

For example, the first frequency deviation detector 28 receives eight correlation peak values from the correlation peak detector 25 and calculates the difference in phase angle between the correlation peak values. For example, eight correlation peak values are set as a first correlation peak value, a second correlation peak value,..., And an eighth correlation peak value, respectively. The correlation peak detector 25 calculates the difference between the phase angle of the first correlation peak value and the phase angle of the second correlation peak value when calculating the phase angle difference between the correlation peak values. The difference between the phase angle of the correlation peak value and the phase angle of the third correlation peak value, ..., the difference between the phase angle of the first correlation peak value and the phase angle of the eighth correlation peak value Etc. are calculated respectively. Then, the first frequency deviation detector 28 calculates the phase rotation amount between the correlation peak positions from the phase angle difference, and converts the phase rotation amount into the frequency deviation Δf ₁ by a predetermined conversion formula. Since the conversion formula for converting the phase rotation amount to the frequency deviation Δf ₁ is known, detailed description thereof is omitted here.

The frequency deviation storage unit 29 receives the frequency deviation Δf ₁ from the first frequency deviation detection unit 28 and the trigger signal from the trigger signal generation unit 27. Further, the frequency deviation storage unit 29 receives a reset signal from the reset signal generation unit 37.

When the trigger signal is input (when the trigger signal is ON), the frequency deviation storage unit 29 stores and holds the input frequency deviation Δf ₁ . The trigger signal is input from the trigger signal generation unit 27 when frame synchronization is established in the first TDD subframe at the start of communication, and when frame synchronization is established in the second TDD subframe at the start of communication. Not entered. It is also not input when frame synchronization is estimated in the third and subsequent TDD subframes at the start of communication. The frequency deviation Δf ₁ is detected in the first TDD subframe at the start of communication, and is already input from the first frequency deviation detector 28 when the trigger signal is input. Then, the frequency deviation storage unit 29 outputs the held frequency deviation Δf ₁ to the addition unit 30.

Thereby, only the frequency deviation Δf ₁ detected in the first TDD subframe at the start of communication is held in the frequency deviation storage unit 29 and output to the addition unit 30. The frequency deviation Δf ₁ detected in the second and subsequent TDD subframes is not held in the frequency deviation storage unit 29. The adder 30 described later outputs the frequency deviation Δf ₁ to the averaging unit 54, and the _NCO 31 described later outputs a sine wave digital signal having a correction value (f _NCO = f _c −Δf ′ ₁ ) as an oscillation frequency to the QDM 20 and the switch 38. The frequency deviation Δf ′ ₁ is an average value of the frequency deviation Δf ₁ in all branches, and is calculated by the averaging unit 54. The processing of the averaging unit 54 will be described later.

When the reset signal is input, the frequency deviation storage unit 29 deletes the stored and held frequency deviation Δf ₁ . Then, the frequency deviation storage unit 29 outputs a null signal to the addition unit 30.

Thereby, when frame synchronization cannot be established, symbol synchronization cannot be established, or when the C / N ratio is smaller than a predetermined threshold value, it is determined that communication has been interrupted, and the frequency deviation storage unit 29 The frequency deviation Δf ₁ held in is deleted (reset). Then, the new frequency deviation Δf ₁ detected in the first TDD subframe when communication is resumed after normalization (communication start) is held in the frequency deviation storage unit 29.

  When a reset signal is output from the reset signal generator 37, a null signal is output to the adder 30 also from the second frequency deviation detector 36 described later. Therefore, the adding unit 30 described later outputs a null signal to the averaging unit 54 described later.

Thus, frequency deviation Δf ₁ is detected using the first TDD subframe at the start of communication, and frequency deviation Δf ′ ₁ of the received signal is corrected in QDM 20. The correction of the frequency deviation Δf ′ ₁ is performed from the beginning of the header following the preamble included in the first TDD subframe at the start of communication. The header part and the payload part in which the frequency deviation Δf ′ ₁ is corrected are the LPF 21 and the payload part. The data is input to the FFT calculation unit 34 via the DS 22.

The accuracy of the frequency deviations Δf ₁ and Δf ′ ₁ depends on the length of the preamble included in the TDD subframe. When the preamble is long, more accurate frequency deviations Δf ₁ and Δf ′ ₁ are detected than when the preamble is short, but the transmission efficiency is lowered. On the other hand, in order to avoid a decrease in transmission efficiency, when the length of the preamble is set to a minimum length necessary for detecting frame synchronization or the like, the frequency deviations Δf ₁ and Δf ′ ₁ with sufficient accuracy are set. It cannot be detected. For this reason, only by correcting the frequency deviation Δf ′ ₁ for the received signal, the frequency deviation remains, and further correction is required.

Therefore, at the second frequency deviation detecting unit 36, using the pilot carrier extracted by the pilot carrier extraction unit 35, a frequency deviation remaining is detected as frequency deviation Delta] f _2, addition section 30 to be described later, the frequency The deviation (Δf ₁ + Δf ₂ ) is output to the averaging unit 54, and the _NCO 31 described later outputs a sine wave digital signal having a correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) as an oscillation frequency to the QDM 20. To do. The average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) is an average value of the added values of the frequency deviation Δf ₁ and the frequency deviation Δf ₂ in all branches, and is calculated by the averaging unit 54. The processing of the averaging unit 54 will be described later.

Thus, the frequency deviation Δf ₂ is detected using the first TDD subframe at the start of communication, and the frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) of the received signal is corrected in the QDM 20. Correction of the frequency deviation _{(Δf '1 + Δf' 2} ) is carried out from the second TDD subframe at the start of communication, the frequency deviation _{(Δf '1 + Δf' 2} ) a header portion and a payload portion which is corrected, The data is input to the FFT calculation unit 34 via the LPF 21 and the DS 22. This process is performed for the TDD subframe after the third, the frequency deviation remaining gradually decreases, the accuracy of the frequency deviation _{(Δf '1 + Δf' 2} ) gradually increases.

  The pilot carrier extraction unit 35 receives the frequency domain reception signal from the FFT calculation unit 34, extracts a pilot carrier at a predetermined position from the carrier of the reception signal, and outputs the pilot carrier to the second frequency deviation detection unit 36.

The second frequency deviation detector 36 receives a pilot carrier from the pilot carrier extractor 35 and also receives a reset signal from the reset signal generator 37. When the pilot carrier is input, the second frequency deviation detector 36 calculates a complex division value at a predetermined symbol interval based on the pilot carrier, calculates a phase rotation amount from the complex division value, and calculates a frequency from the phase rotation amount. Deviation Δf ⁱ ₂ is detected. i indicates the number of the TDD subframe. Then, the second frequency deviation detector 36 accumulates the detected frequency deviation Δf ⁱ ₂ for each subframe and outputs the accumulated frequency deviation Δf ₂ to the adder 30.

When receiving the reset signal, the second frequency deviation detector 36 deletes the frequency deviation Δf ₂ and outputs a null signal to the adder 30.

The adding unit 30 inputs the frequency deviation Δf ₁ from the frequency deviation storage unit 29, inputs the frequency deviation Δf ₂ from the second frequency deviation detecting unit 36, adds the frequency deviation Δf ₁ and the frequency deviation Δf ₂ , The addition result (Δf ₁ + Δf ₂ ) is output to the averaging unit 54.

The averaging unit 54 used in common to all branches inputs the addition result (Δf ₁ + Δf ₂ ) from the addition unit 30 of each branch, calculates the average value of the addition results (Δf ₁ + Δf ₂ ) of each branch, An average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) that is an average value of the frequency deviations of the branches is output to the NCO 31 of each branch.

The oscillator 50 used in common to all branches outputs a sine wave digital signal having an oscillation frequency of a predetermined value f _c to the NCO 31 and the switch 38 of each branch.

NCO31 is a local oscillator, and inputs from the oscillator 50 to the sine-wave digital signal of the oscillation frequency of the default value f _c, enter the average frequency deviation _{(Δf '1 + Δf' 2} ) from the average unit 54, the default value f _c is corrected by subtracting the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) to generate a sine wave digital signal with the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) as the oscillation frequency. The sine wave digital signal is output to the QDM 20 and the switch 38.

The switch 38 is set in advance so that the oscillator 50 and the QM 14 are connected. Accordingly, the sine-wave digital signal of the oscillation frequency of the default values f _c which is output from the oscillator 50 is input to QM14 via the switch 38. The switch 38 can select either the default value f _c or the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ), but selects only the default value f _c. And

Here, when the frequency deviation Δf ₁ is detected using the first TDD subframe at the start of communication, the adding unit 30 inputs the frequency deviation Δf ₁ from the frequency deviation storage unit 29, and A null signal is input from the frequency deviation detection unit 36, and the addition result Δf ₁ is output to the averaging unit 54. The NCO 31 receives the average frequency deviation (Δf ′ ₁ ) from the averaging unit 54 and outputs a sine wave digital signal having the correction value (f _NCO = f _c −Δf ′ ₁ ) as the oscillation frequency to the QDM 20 and the switch 38. To do. As a result, the frequency deviation Δf ′ ₁ of the received signal is corrected in the QDM 20. It is assumed that the average frequency deviation (Δf ′ ₁ ) is calculated by the averaging unit 54.

When the frequency deviation Δf ₂ is detected using the first TDD subframe at the start of communication, the adding unit 30 inputs the frequency deviation Δf ₁ from the frequency deviation storage unit 29 and also receives the second frequency The frequency deviation Δf ₂ is input from the deviation detection unit 36 and the addition result (Δf ₁ + Δf ₂ ) is output to the averaging unit 54. The NCO 31 receives the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) from the averaging unit 54 and uses a correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) as a sine wave digital signal. Is output to the QDM 20 and the switch 38. As a result, the frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) of the received signal is corrected in the QDM 20. The same applies when the frequency deviation Δf ₂ is detected using the second and subsequent TDD subframes at the start of communication.

In this manner, the frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) of the received signal is corrected in the modem 5-1 of the MS 1-1.

(BS2-1 / Example 1)
Next, the BS 2-1 shown in FIG. 2 will be described in detail. FIG. 4 is a block diagram showing the configuration of BS2-1. The BS 2-1 includes an antenna 6, a switch 60, an RF unit 7-1, and a modem unit 8-1. The RF unit 7-1 and the modulation / demodulation unit 8-1 illustrated in FIG. 4 indicate the configuration of one branch among the four branches in the RF unit 7-1 and the modulation / demodulation unit 8-1 illustrated in FIG. ing. The switch 60 shown in FIG. 4 corresponds to the switch 60 of the RF unit 7-1 shown in FIG. 2, but is shown to be installed outside the RF unit 7-1 for the sake of explanation.

  The lower part of BS2-1 shown in FIG. 4 is a transmission processing block part, and the upper part is a reception processing block part. Specifically, the U / C 72 of the RF unit 7-1 and the IFFT calculation unit 85,..., QM89, and the D / A conversion unit 82 of the modem unit 8-1 constitute a transmission processing block unit. . A reception processing block by the D / C 71 of the RF unit 7-1 and the A / D conversion unit 81, the QDM 92,..., The second frequency deviation detection unit 108 and the reset signal generation unit 109 of the modem unit 8-1. The part is composed.

  The switch 60 corresponds to the switch 60 of the BS 2-1 shown in FIG. 2, receives a switching signal from a frame synchronization detecting unit 98 of the modem unit 8-1 described later, and switches the internal switch based on the switching signal. Switching to the reception side (D / C 71 side of an RF unit 7-1 described later) or the transmission side (U / C 72 side of an RF unit 7-1 described later).

(RF section 7-1)
The RF unit 7-1 includes a D / C 71 and a U / C 72 in a one-branch configuration. The local oscillator 70 is used in common for all branches.

  The D / C 71 corresponds to the D / C 71 of the BS 2-1 shown in FIG. 2, inputs an RF signal transmitted from the MS 1-1 and received by the antenna 6 through the switch 60, and output by the local oscillator 70. The RF signal is frequency-converted into an IF signal based on a sine wave digital signal having an oscillation frequency of a predetermined value Lo.

  The U / C 72 corresponds to the U / C 72 of the BS 2-1 shown in FIG. Based on the sine wave signal (the same sine wave signal as the sine wave signal used by the D / C 71), the IF signal is frequency-converted into an RF signal, and the RF signal is output to the switch 60. Thereby, the RF signal is transmitted through the switch 60 and the antenna 6.

(Modulator / Demodulator 8-1)
The modem unit 8-1 includes a transmission processing unit shown in the lower stage and a reception processing unit shown in the upper stage in a one-branch configuration. The oscillator 80 and the average unit 84 are used in common for all branches.

The transmission processing unit includes an IFFT calculation unit 85, a GI addition unit 86, a US 87, an LPF 88, a QM 89, and a D / A conversion unit 82. Comparing the transmission processing unit shown in FIG. 4 with the transmission processing unit shown in FIG. 3, the QM 89 shown in FIG. 4 receives the sine wave digital signal input from the NCO 103, and the QM 14 shown in FIG. This is different in that it is different from a sine wave digital signal input via the sine wave. Specifically, QM14 from the oscillator 50 through the switch 38, whereas inputs the sine-wave digital signal of the oscillation frequency of the default values f _c, QM89 from NCO103, predetermined value (correction value) ( f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ )) is input as a sine wave digital signal having an oscillation frequency.

  The IFFT calculation unit 85, GI addition unit 86, US87, LPF 88, and D / A conversion unit 82 shown in FIG. 4 are the IFFT calculation unit 10, GI addition unit 11, US12, LPF 13, and D / A conversion unit shown in FIG. Since the same processing is performed corresponding to each of 52, detailed description is omitted.

The QM 89 receives the modulated signal after the filter processing from the LPF 88 and also outputs a sine wave digital signal (correction value f _NCO (= f _c −Δf ″ ₁ −Δf ″ ₂ ) from the _NCO 103 as an oscillation frequency. Signal), digital quadrature modulation is performed on the modulated signal based on the sine wave digital signal, and the transmission signal after digital quadrature modulation is output to the D / A converter 82.

In this way, the digital quadrature modulation is performed from BS 2-1 at the oscillation frequency of the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ), and the frequency at the oscillation frequency of the fixed default value Lo. The converted RF signal (RF signal of radio frequency f ₂ ) is transmitted.

The reception processing unit includes an A / D conversion unit 81, a QDM 92, an LPF 93, a DS 94, a preamble storage unit 95, a mobile correlation unit 96, a correlation peak detection unit 97, a frame synchronization detection unit 98, a trigger signal generation unit 99, and a first frequency. Deviation detection unit 100, frequency deviation storage unit 101, addition unit 102, NCO 103, symbol synchronization detection unit 104, FFT window timing unit 105, FFT operation unit 106, pilot carrier extraction unit 107, second frequency deviation detection unit 108 and reset A signal generation unit 109 is provided. In this case, LPF 93, DS 94, preamble storage unit 95, mobile correlation unit 96, correlation peak detection unit 97, frame synchronization detection unit 98, trigger signal generation unit 99, first frequency deviation detection unit 100, frequency deviation storage unit 101, The adder 102, the symbol synchronization detector 104, the FFT window timing unit 105, the FFT calculator 106, the pilot carrier extractor 107, the second frequency deviation detector 108, and the reset signal generator 109 provide a frequency deviation (Δf ₁ + Δf ₂ ) Is detected. The same applies to Examples 2 to 4 described later.

  When the reception processing unit illustrated in FIG. 4 is compared with the reception processing unit illustrated in FIG. 3, the reception processing unit illustrated in FIG. 4 is different in that the switch 38 illustrated in FIG. 3 is not provided. Since other configurations are the same, detailed description is omitted.

Here, the adding unit 102 outputs the addition result (Δf ₁ + Δf ₂ ) of the frequency deviation Δf ₁ and the frequency deviation Δf ₂ to the averaging unit 84. The averaging unit 84 used in common to all branches inputs the addition result (Δf ₁ + Δf ₂ ) from the addition unit 102 of each branch, calculates the average value of the addition results (Δf ₁ + Δf ₂ ) of all branches, An average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) that is an average value of the frequency deviations of the branches is output to the NCO 103 of each branch.

Oscillator 80 used in common for all branches, the sine-wave digital signal of the oscillation frequency of the default values f _c, and outputs the NCO103 of each branch.

NCO103 are local oscillator inputs with the oscillator 80 for inputting a sine-wave digital signal of the oscillation frequency of the default values f _c, the average frequency deviation from the mean section 84 _{(Δf '' 1 + Δf '} ' 2), the default The value f _c is corrected by subtracting the average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ), and the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ) is used as the oscillation frequency. A wave digital signal is generated, and the sine wave digital signal is output to Q D M92 and QM89. Thus, in QDM92, frequency deviation of the received signal _{(Δf '' 1 + Δf '} ' 2) is corrected, at QM89, frequency deviation of the transmit signal _{(Δf '' 1 + Δf '} ' 2) is corrected.

Here, when the frequency deviation Δf ₁ is detected using the first TDD subframe at the start of communication, the adding unit 102 inputs the frequency deviation Δf ₁ from the frequency deviation storage unit 101, and A null signal is input from the frequency deviation detection unit 108, and the addition result Δf ₁ is output to the averaging unit 84. The NCO 103 receives the average frequency deviation (Δf ″ ₁ ) from the averaging unit 84, and outputs a sine wave digital signal having the correction value (f _NCO = f _c −Δf ″ ₁ ) as the oscillation frequency to the QDM 92 and the QM 89. Output. Thus, in QDM92, frequency deviation Delta] f 'of the received signal' ₁ is corrected, in QM89, frequency deviation Delta] f of the transmission signal _'1 is corrected. Note that the average frequency deviation (Δf ″ ₁ ) is calculated by the averaging unit 84.

In addition, when the frequency deviation Δf ₂ is detected using the first TDD subframe at the start of communication, the adding unit 102 inputs the frequency deviation Δf ₁ from the frequency deviation storage unit 101 and the second frequency The frequency deviation Δf ₂ is input from the deviation detector 108, and the addition result (Δf ₁ + Δf ₂ ) is output to the average unit 84. Then, NCO103 inputs the average frequency deviation from the mean section _{84 (Δf '' 1 + Δf} '' 2), the correction value _{(f NCO = f c -Δf '} ' 1 -Δf '' 2) is the oscillation frequency A sine wave digital signal is output to QDM 92 and QM 89. As a result, the frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) of the received signal is corrected in the QDM 92, and the frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) of the transmission signal is corrected in the QM 89 . The same applies when the frequency deviation Δf ₂ is detected using the second and subsequent TDD subframes at the start of communication.

Thus, the modem unit 8-1 BS 2-1, the frequency deviation of the received signal _{(Δf '' 1 + Δf '} ' 2) is corrected, the frequency deviation of the transmit signal _{(Δf '' 1 + Δf '} ' 2) is It is corrected.

(Frequency deviation correction processing / Example 1)
Next, in the wireless communication system according to the first embodiment illustrated in FIG. 2, the radio frequency of the RF signal transmitted from the RF unit 4-1 of the MS 1-1 is transmitted from the RF unit 7-1 of the BS 2-1. A process for correcting the deviation of the RF signal from the radio frequency and matching the radio frequencies of all paths will be described. As described above, the radio frequency of the RF signal transmitted from the RF unit 4-1 of the MS 1-1 is constant without changing, and the radio frequency of the RF signal transmitted from the RF unit 7-1 of the BS 2-1 is It changes according to the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ) output from the _NCO 103.

FIG. 5 is a flowchart illustrating processing for correcting and matching radio frequency deviation in the first embodiment. First, the MS 1-1 transmits an RF signal simultaneously from each branch (step S501). Specifically, the QM14 of modem units 5-1 in MS1-1, quadrature modulation is performed on the basis of the oscillator 50 to the sine-wave digital signal of the oscillation frequency of the default values f _c, the RF unit 4-1 U / By C42, the frequency is converted into an RF signal based on the sine wave signal having the oscillation frequency of the default value Lo in the local oscillator 40, and the RF signal is transmitted from the branch of the MS1-1. The radio frequency of this RF signal is fixed.

BS2-1 detects an average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) between MS 1-1 and BS 2-1 (step S502). Specifically, the D / C 71 of the RF unit 7-1 in the BS 2-1 converts the frequency of the received RF signal into an IF signal based on a sine wave signal having a predetermined frequency Lo in the local oscillator 70. . The first frequency deviation Δf ₁ is detected by the first frequency deviation detector 100 of the modem 8-1, and the second frequency deviation Δf ₂ is detected by the second frequency deviation detector 108, The average unit 84 calculates the average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ).

The BS 2-1 performs quadrature modulation on the transmission signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ) in all branches, and transmits the RF signal to the MS 1-1 ( Step S503). Specifically, a correction value (f _NCO = f _c −Δf ′) obtained by correcting the predetermined value f _c with a frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) by the QM 89 of the modem 8-1 in the BS 2-1. Quadrature modulation is performed based on a sine wave digital signal having an oscillation frequency of ' ₁ −Δf ″ ₂ ). Then, the U / C 72 of the RF unit 7-1 converts the frequency into an RF signal based on the sine wave signal having the oscillation frequency of the predetermined value Lo in the local oscillator 70, and the RF signal is transmitted from the BS 2-1. The radio frequency of the RF signal changes according to the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ). That is, the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″) in which the average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) between the MS 1-1 and BS 2-1 is reflected by the QM 89. _The quadrature modulation is performed based on the sine wave digital signal having the oscillation frequency of ₂ ).

The BS 2-1 performs orthogonal demodulation on the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ) in all branches, and continues the demodulation process (step S504). Specifically, the D / C 71 of the RF unit 7-1 in the BS 2-1 converts the frequency of the received RF signal into an IF signal based on a sine wave signal having a predetermined frequency Lo in the local oscillator 70. . By QDM92 the modem unit 8-1, the default value f _c is the frequency deviation _{(Δf '' 1 + Δf '} ' 2) corrected correction value _{(f NCO = f c -Δf '} ' 1 -Δf '' 2 The quadrature demodulation is performed on the basis of the sine wave digital signal of the oscillation frequency. That is, the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″) in which the average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) between the MS 1-1 and BS 2-1 is reflected by the QDM 92. _The quadrature demodulation is performed based on the sine wave digital signal having the oscillation frequency of ₂ ).

FIG. 6 is a diagram for explaining the radio frequency of the process shown in FIG. Let the radio frequency of the RF signal transmitted from the MS 1-1 be f _1, and let the radio frequency of the RF signal transmitted from the BS 2-1 be f ₂ . When an RF signal having a radio frequency f ₁ is transmitted from the MS 1-1 at the start of communication, between the oscillation frequency of the local oscillator 40 of the MS 1-1 and the oscillation frequency of the local oscillator 70 of the BS 2-1 at the BS 2-1. A frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) corresponding to the above deviation is detected. Then, quadrature demodulation is performed by the QDM 92 based on the sinusoidal digital signal having the oscillation frequency of the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ), and the correction value (f _NCO = quadrature modulation is performed on the basis of f _c -.DELTA.f '' ₁ -.DELTA.f 'sinusoidal digital signal of the oscillation frequency of the' _2). The radio frequency f ₂ of the RF signal transmitted from the BS 2-1 always matches the radio frequency f _{1 of the} RF signal transmitted from the MS 1-1 from the beginning.

Here, the frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) is the oscillation frequency of the default value Lo of the local oscillator 40 used by the U / C 42 of the MS 1-1 and the local frequency used by the D / C 71 of the BS 2-1. This is a deviation from the oscillation frequency of the predetermined value Lo of the oscillator 70. The local oscillator 70 used by the D / C 71 and U / C 72 of the BS 2-1 is common. Therefore, the radio frequency f ₂ of the RF signal transmitted from the BS 2-1 changes to a frequency in which the frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) is corrected, and as a result, the RF transmitted from the MS 1-1. It naturally matches the radio frequency f _{1 of the} signal.

Returning to FIG. 5, the MS 1-1 detects the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) between the MS 1-1 and the BS 2-1 (step S 505). Specifically, the received RF signal is frequency-converted into an IF signal by the D / C 41 of the RF unit 4-1 in the MS 1-1 based on the sine wave signal having the oscillation frequency of the default value Lo in the local oscillator 40. . The first frequency deviation Δf ₁ is detected by the first frequency deviation detector 28 of the modem 5-1, and the second frequency deviation Δf ₂ is detected by the second frequency deviation detector 36, An average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) is calculated by the average unit 54.

In all branches, the MS 1-1 performs quadrature modulation on the transmission signal at the oscillation frequency of the predetermined value f _c and transmits the RF signal to the BS 2-1 (step S506). The frequency correction of the transmission signal is not performed. Specifically, the QM14 of modem units 5-1 in MS1-1, quadrature modulation is performed on the basis of the sine-wave digital signal of the oscillation frequency of the default values f _c. Then, the U / C 42 of the RF unit 4-1 converts the frequency into an RF signal based on the sine wave signal of the oscillation frequency of the predetermined value Lo in the local oscillator 40, and the RF signal is transmitted from the MS 1-1.

The MS 1-1 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) in all branches, and continues the demodulation process (step S507). Specifically, the received RF signal is frequency-converted into an IF signal by the D / C 41 of the RF unit 4-1 in the MS 1-1 based on the sine wave signal having the oscillation frequency of the default value Lo in the local oscillator 40. . Then, the oscillation frequency of the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) obtained by correcting the predetermined value f _c with the frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) by the QDM 20 of the modem unit 5-1. Quadrature demodulation is performed based on the sine wave digital signal. That is, the oscillation of the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) reflecting the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) between the MS 1-1 and the BS 2-1 by the QDM 20. Quadrature demodulation is performed based on a frequency sine wave digital signal.

However, the frequency deviation (Δf ₁ + Δf ₂ ) detected in each branch of the modulation / demodulation unit 5-1 in the MS 1-1 and the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) of all the branches are the modulation / demodulation unit 8 in the BS 2-1. Since the frequency deviation (Δf ₁ ″ + Δf ₂ ″) is corrected in each branch of −1, the value is ideally close to zero.

And this process transfers to step S502 from step S506 and step S507, and repeats step S502-step S507. Even the second or subsequent processing, the modem unit 5-1 MS1-1 are orthogonal modulates the transmission signal at the oscillation frequency of the default values f _c.

  As described above, with reference to the radio frequency of the RF signal transmitted from the MS 1-1, the MS 1-1 and the BS 2-1 operate in a state where the frequency of each unit is synchronized with the radio frequency.

As described above, according to the wireless communication system of the first embodiment, when each branch of the MS 1-1 uses the common local oscillator 40 and each branch of the BS 2-1 uses the common local oscillator 70, the MS 1 −1 branches orthogonally modulate the transmission signal at the oscillation frequency of the default value f _c , frequency-convert the transmission signal at the oscillation frequency of the default value Lo in the local oscillator 40, and the RF signal of the reference radio frequency Was sent. Each branch of BS2-1 has an average frequency deviation (Δf ″ ₁ + Δf ″ ₂ ) of all the branches reflecting the frequency deviation between the local oscillator 40 of MS1-1 and the local oscillator 70 of BS2-1. ) Is detected, and at the oscillation frequency of the correction value (f _NCO = f _c −Δf ″ ₁ −Δf ″ ₂ ), quadrature modulation is performed and an RF signal is transmitted, and quadrature demodulation is performed. .

Thereby, the radio frequency of the RF signal transmitted from the BS 2-1 can be matched with the radio frequency of the RF signal transmitted from the MS 1-1. That is, the state changes from the state where the radio frequency deviation exists between the MS 1-1 and the BS 2-1 to the state where there is no radio frequency deviation. In MS1-1 and BS2-1, there is no radio frequency deviation between the branches from the beginning of communication. As a result , the radio frequencies of all RF signals transmitted from the MS 1-1 and BS 2-1 match.

  Therefore, transmission from the RF unit 7-1 of the BS 2-1 to the radio frequency of the RF signal transmitted from the RF unit 4-1 of the MS 1-1 is performed within the wireless communication system without using an external reference signal. It is possible to match the radio frequency of the RF signal to be made with high accuracy.

[Example 2]
Next, Example 2 will be described. In the second embodiment, when each branch of the MS uses a common local oscillator and each branch of the BS uses an independent local oscillator, the radio frequencies of all the RF signals transmitted are the same as in the first embodiment. Is an example of matching.

  FIG. 7 is a block diagram illustrating the overall configuration of the wireless communication system according to the second embodiment. The wireless communication system according to the second embodiment includes an MS 1-2 including four antennas 3, an RF unit 4-1, and a modem unit 5-1, four antennas 6, an RF unit 7-2, and a modem unit 8-. 2 with BS2-2. The wireless communication system according to the second embodiment corresponds to a wireless communication system in which the antennas 201-5 and 201-6 and the RF units 202-5 and 202-6 are removed from the wireless communication system illustrated in FIG.

  In the second embodiment, in the MS 1-2, the RF unit 4-1 corresponding to the four antennas 3 is mounted in one RF device, distributes the signal of one local oscillator 40, and is common to each branch. To use. Further, in the BS 2-2, an RF unit 7-2 corresponding to each of the four antennas 6 is mounted in an individual RF device for each branch, and the local oscillator 70 is also used independently.

  In the second embodiment, there is a frequency deviation between MS1-2 and BS2-2. In MS1-2, there is no frequency deviation between branches. In BS2-2, there is a frequency deviation between branches. Exists.

  The RF unit 4-1 and the modem unit 5-1 of the MS1-2 are the same as the configuration of the first embodiment shown in FIG.

  The branch of the RF unit 7-2 in the BS 2-2 includes a local oscillator 70 different from other branches, and includes a switch 60, a D / C 71, and a U / C 72. Since the local oscillator 70, the switch 60, the D / C 71, and the U / C 72 have already been described with reference to FIG. 2, description thereof is omitted here.

  The modulation / demodulation unit 8-2 of the BS 2-2 includes one oscillator 80, an A / D conversion unit 81 and a D / A conversion unit 82 for each branch, and one signal processing unit 112. The signal processing unit 112 includes a processing unit for each branch, and includes, for example, an FPGA.

  Since the local oscillator 40 of the RF unit 4-1 in the MS 1-2 is common to all branches, the frequency deviation between the branches is zero. Since the local oscillator 70 of the RF unit 7-2 is different between the branches, there is a frequency deviation between the branches. On the other hand, the oscillation frequency of the sine wave signal output by the local oscillator 40 of the RF unit 4-1 in the MS 1-2 and the sine wave signal output by the local oscillator 70 of the RF unit 7-1 for each branch in the BS 2-2. There is a frequency deviation due to the individual difference. For this reason, the frequency deviation between each branch of MS1-2 and BS2-2 is corrected, and the frequency of the RF signal transmitted from MS1-2 to BS2-2 and transmitted from BS2-2 to MS1-2. It is necessary to match the frequency of the RF signal. Hereinafter, a process of correcting the frequency deviation and matching the frequencies of the RF signals will be described.

(MS1-2 / Example 2)
Since MS1-2 shown in FIG. 7 is the same as MS1-1 of Example 1 shown in FIG. 3, description thereof is omitted here.

(BS2-2 / Example 2)
The BS 2-2 shown in FIG. 7 will be described in detail. FIG. 8 is a block diagram showing the configuration of BS2-2. The BS 2-2 includes an antenna 6, a switch 60, an RF unit 7-2, and a modem unit 8-2. The RF unit 7-2 and the modulation / demodulation unit 8-2 shown in FIG. 8 show the configuration of one branch among the four branches in the RF unit 7-2 and the modulation / demodulation unit 8-2 shown in FIG. ing. The switch 60 shown in FIG. 8 corresponds to the switch 60 of the RF unit 7-2 shown in FIG. 7, but is shown to be installed outside the RF unit 7-2 for the sake of explanation.

  Similarly to the BS 2-1 of the first embodiment illustrated in FIG. 4, the lower stage of the BS 2-2 illustrated in FIG. 8 is a transmission processing block unit, and the upper stage is a reception processing block unit.

When the BS 2-2 of the second embodiment shown in FIG. 8 is compared with the BS 2-1 of the first embodiment shown in FIG. 4, the local oscillator 70 of the RF unit 7-2 is independent of the BS 2-2 of the second embodiment. This is different from BS 2-1 of the first embodiment in that it is used only for the branch and the NCO 103 directly inputs the frequency deviation (Δf ₁ + Δf ₂ ) from the adder 102.

(Modulator / Demodulator 8-2)
The modem unit 8-2 includes a transmission processing unit shown in the lower stage and a reception processing unit shown in the upper stage in a one-branch configuration. The oscillator 80 is used in common for all branches. The modem unit 8-2 does not include the averaging unit 84 of the first embodiment.

Similar to the first embodiment shown in FIG. 4, the transmission processing unit includes an IFFT calculation unit 85 and the like. Since these components are the same as those of the first embodiment shown in FIG. 4, the description thereof is omitted here. In the second embodiment, the QM 89 receives from the _NCO 103 a sine wave digital signal having a correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) as an oscillation frequency. m indicates a branch number.

In this way, from the branch of BS2-2, digital quadrature modulation is performed at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ), and the oscillation frequency is set to the fixed default value Lo. The frequency-converted RF signal (RF signal of radio frequency f2 _{, m} ) is transmitted.

The reception processing unit includes an A / D conversion unit 81 and the like. Since these components are the same as the components of the first embodiment shown in FIG. In the second embodiment, the adding unit 102 outputs the frequency deviation (Δf _{1, m} + Δf _{2, m} ) to the NCO 103, and the NCO 103 inputs the frequency deviation (Δf _{1, m} + Δf _{2, m} ) from the adding unit 102. Then, a sine wave digital signal having the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) as an oscillation frequency is generated, and the sine wave digital signal is output to the QDM 92 and the QM 89. As a result, the frequency deviation (Δf _{1, m} + Δf _{2, m} ) of the received signal is corrected in the QDM 92, and the frequency deviation (Δf _{1, m} + Δf _{2, m} ) of the transmission signal is corrected in the QM 89.

Thus, in each branch of the modem unit 8-2 of BS 2-2, the frequency deviation of the received signal _{(Δf 1, m + Δf 2} , m) are corrected, the frequency deviation of the transmit signal _{(Δf 1, m + Δf 2} , _m ) is corrected.

(Frequency deviation correction processing / Example 2)
Next, in the radio communication system according to the second embodiment illustrated in FIG. 7, the radio frequency of the RF signal transmitted from the RF unit 4-1 of the MS 1-2 and each branch of the RF unit 7-2 of the BS 2-2 A process for correcting the deviation of the transmitted RF signal from the radio frequency and matching the radio frequencies of all paths will be described. As described above, the radio frequency of the RF signal transmitted from the RF section 4-1 of the MS1-2 is constant without change, and the radio frequency of the RF signal transmitted from each branch of the RF section 7-2 of the BS2-2. The frequency changes according to a correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) output from the _NCO 103.

  FIG. 9 is a flowchart illustrating a process of correcting and matching radio frequency deviations in the second embodiment. First, the MS 1-2 simultaneously transmits an RF signal from each branch (step S901). Step S901 is the same as step S501 shown in FIG.

The BS 2-2 detects the frequency deviation (Δf _{1, m} + Δf _{2, m} ) between the MS 1-2 and the branch of the BS 2-2 for each branch (step S902). Specifically, the D / C 71 of the RF unit 7-2 in the BS 2-2 converts the received RF signal into an IF signal based on the sine wave signal having the oscillation frequency of the default value Lo in the local oscillator 70. . Then, the first frequency deviation Δf _{1, m} is detected by the first frequency deviation detector 100 of the modem unit 8-2, and the second frequency deviation Δf _{2, m} is detected by the second frequency deviation detector 108. Is detected, and the adder 102 calculates a frequency deviation (Δf _{1, m} + Δf _{2, m} ).

The BS 2-2 performs quadrature modulation of the transmission signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) for each branch, and transmits the RF signal to the MS 1-2 ( Step S903). Specifically, a correction value (f _NCO = f _c −Δf ₁ ) obtained by correcting the predetermined value f _c with the frequency deviation (Δf _{1, m} + Δf _{2, m} ) by the QM 89 of the modem unit 8-2 in the BS 2-2. _{, m} −Δf _{2, m} ), quadrature modulation is performed based on a sine wave digital signal having an oscillation frequency. Then, the U / C 72 of the RF unit 7-2 converts the frequency into an RF signal based on the sine wave signal having the oscillation frequency of the predetermined value Lo in the local oscillator 70, and the RF signal is transmitted from the BS 2-2. The radio frequency of the RF signal changes according to the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ).

The BS 2-2 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) for each branch, and continues the demodulation process (step S904). Specifically, the D / C 71 of the RF unit 7-2 in the BS 2-2 converts the received RF signal into an IF signal based on the sine wave signal having the oscillation frequency of the default value Lo in the local oscillator 70. . Then, a correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) obtained by correcting the predetermined value f _c with the frequency deviation (Δf _{1, m} + Δf _{2, m} ) by the QDM 92 of the modem unit 8-2. The quadrature demodulation is performed on the basis of the sine wave digital signal of the oscillation frequency. That is, the correction value (f _NCO = f _c −Δf _{1, m} −Δf ₂ ) reflecting the frequency deviation (Δf _{1, m} + Δf _{2, m} ) between the branch of MS 1-2 and BS 2-2 by the QDM 92 _{. The} quadrature demodulation is performed based on the sine wave digital signal having the oscillation frequency of _m ).

FIG. 10 is a diagram for explaining the radio frequency of the process shown in FIG. The radio frequency of the RF signal transmitted from the MS1-2 and f _1, the radio frequency of the RF signal transmitted from the m-th branch of BS2-2 and f _{2, m.} Hereinafter, “−m” added to the number of the component indicates that the component is the component of the m-th branch.

At the start of communication, the RF signal in a radio frequency f ₁ from MS1-2 are transmitted, the BS 2-2, the oscillation of the local oscillator 70-m at the oscillation frequency and the branch BS 2-2 of the local oscillator 40 of MS1-2 A frequency deviation (Δf _{1, m} + Δf _{2, m} ) corresponding to the deviation between the frequencies is detected. Then, quadrature demodulation is performed by the QDM 92-m based on the sine wave digital signal of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ), and the correction value is acquired by the QM 89-m. quadrature modulation is performed on the basis of _{(f NCO = f c -Δf 1} , m -Δf 2, m) sinusoidal digital signal of the oscillation frequency of. Radio frequency f _{2, m} of the RF signal transmitted from the m-th branch of BS2-2 always from the beginning, matching the radio frequency f ₁ of the RF signal transmitted from MS1- 2.

Here, the frequency deviation (Δf _{1, m} + Δf _{2, m} ) is used by the oscillation frequency of the default value Lo of the local oscillator 40 used by the U / C 42 of the MS 1-2 and the D / C 71-m of the BS 2-2. This is a deviation from the oscillation frequency of the default value Lo of the local oscillator 70-m. The local oscillator 70-m used by the D / C 71-m and the U / C 72-m of the BS 2-2 is common. Therefore, the radio frequency f _{2, m} of the RF signal transmitted from the m-th branch of BS2-2 changes to a frequency in which the frequency deviation (Δf _{1, m} + Δf _{2, m} ) is corrected, and as a result, MS1 -2 naturally matches the radio frequency f ₁ of the RF signal transmitted from -2.

Returning to FIG. 9, MS1-2 detects the average frequency deviation _{(Δf '1 + Δf' 2} ) between the MS1-2 and BS 2-2 (step S905), in all branches, the default value f _c The transmission signal is orthogonally modulated at the oscillation frequency, and the RF signal is transmitted to the BS 2-2 (step S906). The frequency correction of the transmission signal is not performed. Then, the MS 1-2 performs quadrature demodulation on the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf ′ ₁ −Δf ′ ₂ ) in all branches, and continues the demodulation process (step S907). Steps S905 to S907 are the same as steps S505 to S507 shown in FIG.

However, the frequency deviation (Δf ₁ + Δf ₂ ) detected in each branch of the modulation / demodulation unit 5-1 in the MS 1-2 and the average frequency deviation (Δf ′ ₁ + Δf ′ ₂ ) of all branches are the modulation / demodulation unit 8 in the BS 2-2. Since the frequency deviation (Δf _{1, m} + Δf _{2, m} ) is corrected in each of the −2 branches, the value is ideally close to zero.

And this process transfers to step S902 from step S906 and step S907, and repeats step S902-step S907. Even the second or subsequent processing, the modem unit 5-1 MS1-2 are orthogonal modulates the transmission signal at the oscillation frequency of the default values f _c.

  In this way, with reference to the radio frequency of the RF signal transmitted from the MS 1-2, the MS 1-2 and the BS 2-2 operate in a state where the frequency of each unit is synchronized with the radio frequency.

As described above, according to the wireless communication system of the second embodiment, when each branch of MS1-2 uses a common local oscillator 40 and each branch of BS2-2 uses an independent local oscillator 70. each branch of MS1-2 are orthogonal modulated transmission signal at the oscillation frequency of the default values f _c, and frequency conversion of a transmission signal at the oscillation frequency of the default Lo in the local oscillator 40, a primary radio frequency An RF signal was transmitted. Each branch of BS2-2 has a frequency deviation (Δf1 _{, m} + Δf2 _{, m} ) reflecting a frequency deviation between the local oscillator 40 of MS1-2 and the local oscillator 70 of the branch of BS2-2. Is detected, and at the oscillation frequency of the correction value (f _NCO = f _c -Δf _{1, m} -Δf _{2, m} ), quadrature modulation is performed and an RF signal is transmitted, and quadrature demodulation is performed.

  Thereby, the radio frequency of the RF signal transmitted from each branch of BS2-2 can be matched with the radio frequency of the RF signal transmitted from MS1-2. That is, the state changes from a state where a radio frequency deviation exists between each branch of the MS 1-2 and the BS 2-2 to a state where no radio frequency deviation exists. MS1-2 has no radio frequency deviation between branches since the start of communication. The BS 2-2 has a radio frequency deviation between branches since the start of communication, but the radio frequency of each branch matches the radio frequency used as the reference of the RF signal transmitted from the MS 1-2. Changes to a state where there is no radio frequency deviation. As a result, the radio frequencies of all RF signals transmitted from MS1-2 and BS2-2 match.

  Therefore, the radio frequency of the RF signal transmitted from the RF unit 4-1 of the MS1-2 is transmitted from the RF unit 7-2 of the BS2-2 without using the reference signal from the outside in the radio communication system. It is possible to match the radio frequency of the RF signal to be made with high accuracy.

Example 3
Next, Example 3 will be described. In the third embodiment, when each branch of the MS uses an independent local oscillator and each branch of the BS also uses an independent local oscillator, all the RF signals transmitted are the same as in the first embodiment. This is an example of matching radio frequencies.

  FIG. 11 is a block diagram illustrating the overall configuration of the wireless communication system according to the third embodiment. The wireless communication system according to the third embodiment includes an MS 1-3 having four antennas 3, an RF unit 4-2, and a modem unit 5-2, four antennas 6, an RF unit 7-2, and a modem unit 8-. 2 with BS2-3.

  In the third embodiment, in the MS1-3, the RF unit 4-2 corresponding to each of the four antennas 3 is mounted in an individual RF device for each branch, and the local oscillator 40 is also used independently. In the BS 2-3, an RF unit 7-2 corresponding to each of the four antennas 6 is mounted in an individual RF device for each branch, and the local oscillator 70 is also used independently.

  In the third embodiment, there is a frequency deviation between MS1-3 and BS2-3, and there is a frequency deviation between branches in MS1-3 and BS2-3.

  The branch of the RF unit 4-2 in the MS 1-3 includes a local oscillator 40 different from other branches, and includes a switch 55, a D / C 41, and a U / C 42. Since the local oscillator 40, the switch 55, the D / C 41, and the U / C 42 have already been described, description thereof is omitted here.

  The modulation / demodulation unit 5-2 of the MS1-3 includes one oscillator 50, an A / D conversion unit 51 and a D / A conversion unit 52 for each branch, and one signal processing unit 113. The signal processing unit 113 includes a processing unit for each branch, and includes, for example, an FPGA.

  The RF unit 7-2 and the modem unit 8-2 of the BS 2-3 are the same as those of the second embodiment shown in FIG.

  Since the local oscillator 40 of the RF unit 4-2 in the MS1-3 is different between the branches, there is a frequency deviation between the branches. Since the local oscillator 70 of the RF unit 7-2 in the BS 2-3 is also different between the branches, there is a frequency deviation between the branches. On the other hand, the oscillation frequency of the sine wave signal output from the local oscillator 40 of the RF unit 4-2 for each branch in the MS1-3 and the local oscillator 70 of the RF unit 7-2 for each branch in the BS2-3. The oscillation frequency of the sine wave signal has a frequency deviation due to individual differences. Therefore, the frequency deviation between each branch of MS1-3 and each branch of BS2-3 is corrected, the frequency of the RF signal transmitted from MS1-3 to BS2-3, and BS2-3 to MS1-3 It is necessary to make the frequency of the RF signal transmitted to the same. Hereinafter, a process of correcting the frequency deviation and matching the frequencies of the RF signals will be described.

(MS1-3 / Example 3)
The MS1-3 shown in FIG. 11 will be described in detail. FIG. 12 is a block diagram showing a configuration of MS1-3. The MS1-3 includes an antenna 3, a switch 55, an RF unit 4-2, and a modem unit 5-2. The RF unit 4-2 and the modulation / demodulation unit 5-2 illustrated in FIG. 12 indicate the configuration of one branch among the four branches in the RF unit 4-1 and the modulation / demodulation unit 5-1, illustrated in FIG. ing. The switch 55 shown in FIG. 12 corresponds to the switch 55 of the RF unit 4-2 shown in FIG. 11, but is shown to be installed outside the RF unit 4-2 for the sake of explanation.

  Similar to the MS 1-1 of the first embodiment illustrated in FIG. 3, the lower stage of the MS 1-3 illustrated in FIG. 12 is a transmission processing block unit, and the upper stage is a reception processing block unit.

When comparing the MS1-3 of the third embodiment shown in FIG. 12 and the MS1-1 of the first embodiment shown in FIG. 3, the local oscillator 40 of the RF unit 4-2 is independent of the MS1-3 of the third embodiment. This is different from MS 1-1 in the first embodiment in that the NCO 31 is used only for the branch, and the frequency deviation (Δf _{1, n} + Δf _{2, n} ) is directly input from the adder 30. n indicates a branch number.

In the MS 1-3 of the third embodiment, the switch 38 is connected to the oscillator 50 and the QM 14 in the branch (for example, the first branch) of the modulation / demodulation unit 5-2 set as the master branch among the four branches. The QM 14 inputs a fixed sine wave digital signal having an oscillation frequency of a predetermined value f _c from the oscillator 50 via the switch 38.

  In branches other than the master branch of the modem 5-2, the switch 38 is set so that the oscillator 50 and the QM 14 are not connected and the NCO 31 and the QM 14 are not connected within a predetermined time at the start of communication. The NCO 31 and the QM 14 are set to be connected after a predetermined time.

  That is, in the branches other than the master branch of the modem unit 5-2, the sine wave digital signal is not input to the QM 14 within a predetermined time at the start of communication. Thus, the RF signal is not transmitted from the branch within a predetermined time at the start of communication. The QM 14 inputs a sine wave digital signal from the NCO 31 via the switch 38 after a predetermined time. Thereby, after a predetermined time, an RF signal is transmitted from the branch. Here, the predetermined time is, for example, a preset time after starting communication.

(Modem 5-2)
The modulation / demodulation unit 5-2 includes a transmission processing unit illustrated in the lower stage and a reception processing unit illustrated in the upper stage in a one-branch configuration. The oscillator 50 is used in common for all branches. The modem 5-2 does not include the average unit 54 of the first embodiment.

  Similar to the first embodiment shown in FIG. 3, the transmission processing unit includes an IFFT calculation unit 10 and the like. Since these components are the same as those in the first embodiment shown in FIG. 3, the description thereof is omitted here.

The master branch of the modem unit 5-2, QM14 is always from the oscillator 50 via a switch 38, and inputs the sine wave digital signal of the oscillation frequency of the default values f _c. As a result, a reference RF signal is always transmitted from the master branch. In branches other than the master branch of the modem 5-2, the QM 14 does not input a sine wave digital signal within a predetermined time at the start of communication, and after a predetermined time, the correction value (f A sine wave digital signal whose oscillation frequency is _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) is input. Thereby, the RF signal is not transmitted from the branch within a predetermined time at the start of communication, and the RF signal is transmitted from the branch after the predetermined time.

  In branches other than the master branch, a control unit (not shown) outputs a sine wave digital signal indicating a predetermined time at the start of communication or after a predetermined time to the switch 38 and the QM 14. The switch 38 is set so that the oscillator 50 and the QM 14 are disconnected and the NCO 31 and the QM 14 are disconnected when a sine wave digital signal indicating a predetermined time at the start of communication is input. Is set so that the NCO 31 and the QM 14 are connected. In addition, when a sine wave digital signal indicating a predetermined time at the start of communication is input, the QM 14 does not output a signal. The data is output to the / A converter 52.

  Note that the switch 38 of the master branch is set in advance so that the oscillator 50 and the QM 14 are connected, and does not input the above-described sine wave digital signal.

Thus, the master branch of MS1-3, defaults are digitally quadrature modulated by the oscillation frequency of f _c, and the frequency-converted RF signal by the oscillation frequency of the fixed default value Lo (fixed radio fixed frequency f ₁ RF signal) is always transmitted. Further, the RF signal is not transmitted from a branch other than the master branch of MS1-3 within a predetermined time at the start of communication, and after a predetermined time, a correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) Is subjected to digital quadrature modulation at the oscillation frequency and frequency-converted at a fixed default value Lo oscillation frequency.

The reception processing unit includes an A / D conversion unit 51 and the like. Since these components are the same as the components of the first embodiment shown in FIG. In the third embodiment, the adding unit 30 outputs the frequency deviation (Δf _{1, n} + Δf _{2, n} ) to the NCO 31, and the NCO 31 inputs the frequency deviation (Δf _{1, n} + Δf _{2, n} ) from the adding unit 30. Then, a sine wave digital signal having the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) as an oscillation frequency is generated, and the sine wave digital signal is output to the QDM 20 and the switch 38. As a result, the frequency deviation (Δf _{1, n} + Δf _{2, n} ) of the received signal is corrected in the QDM 20.

When the switch 38 is switched to connect the NCO 31 and the QM 14, the QM 14 uses the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) from the _NCO 31 as the oscillation frequency. A sine wave digital signal is input, and the frequency deviation (Δf _{1, n} + Δf _{2, n} ) of the transmission signal is corrected.

In this way, the frequency deviation (Δf _{1, n} + Δf _{2, n} ) of the received signal is corrected in the modulation / demodulation unit 5-2 of the MS 1-3.

(BS2-3 / Example 3)
Since the BS 2-3 shown in FIG. 11 is the same as the BS 2-2 of the second embodiment shown in FIG. 7, the description thereof is omitted here.

(Frequency deviation correction processing / Example 3)
Next, in the radio communication system according to the third embodiment illustrated in FIG. 11, the radio frequency of the RF signal transmitted from each branch of the RF unit 4-2 of the MS1-3 and the RF unit 7-2 of the BS2-3 A process for correcting the deviation between the RF signal transmitted from each branch and the radio frequency and matching the radio frequencies of all paths will be described.

As described above, within a predetermined time at the start of communication, the RF signal transmitted from MS1-3 is an RF signal from only the master branch, and its radio frequency does not change and is constant. Radio frequency RF signals transmitted from each branch of BS2-3 changes according to the correction value output from _{NCO103 (f NCO = f c -Δf} 1, m -Δf 2, m), communication start time When the frequency deviation is corrected within the predetermined time, it matches the radio frequency of the RF signal transmitted from the master branch of MS1-3. Then, after a predetermined time, the radio frequency of the RF signal transmitted from the branch other than the master branch of MS1-3 is the correction value (f _NCO = f _c −Δf _{1, n} −Δf _2, output from the _NCO 31) _{. n} ) varies according to

FIG. 13 is a flowchart illustrating processing for correcting and matching radio frequency deviation in the third embodiment. First, the MS 1-3 transmits an RF signal from the master branch (for example, the first branch) (step S1301). Specifically, the QM14 master branch of modem units 5-2 in MS1-3, quadrature modulation on the basis of the oscillator 50 to the sine-wave digital signal of the oscillation frequency of the default values f _c is performed, RF unit 4-2 The U / C 42 converts the frequency to an RF signal based on the sine wave signal having the oscillation frequency of the predetermined value Lo in the local oscillator 40, and transmits the RF signal from the master branch of the MS1-3. The radio frequency of this RF signal does not change and is constant. RF signals are not transmitted from other branches.

BS2-3 detects the frequency deviation (Δf _{1, m} + Δf _{2, m} ) between the master branch of MS1-3 and the branch of BS2-3 for each branch (step S1302), and corrects for each branch. The transmission signal is orthogonally modulated at the oscillation frequency of the value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ), and the RF signal is transmitted to MS1-3 (step S1303). Then, the BS 2-3 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) for each branch, and continues the demodulation process (step S1304). ). Steps S1302 to S1304 are the same as steps S902 to S904 shown in FIG.

MS1-3 detects the frequency deviation (Δf _{1, n} + Δf _{2, n} ) between MS1-3 and BS2-3 for each branch (step S1305). Specifically, the received RF signal is frequency-converted into an IF signal by the D / C 41 of the RF unit 4-2 in the MS1-3 based on a sine wave signal having an oscillation frequency of the default value Lo in the local oscillator 40. . The first frequency deviation Δf _{1, n} is detected by the first frequency deviation detector 28 of the modem 5-2, and the second frequency deviation Δf _{2, n} is detected by the second frequency deviation detector 36. Is detected, and the frequency deviation (Δf _{1, n} + Δf _{2, n} ) is calculated by the adder 30.

MS1-3, in master branch, orthogonally modulates the transmission signal at the oscillation frequency of the default values f _c, and transmits the RF signal to BS2-3, the branch other than the master branch correction value (f _NCO = f _The transmission signal is quadrature-modulated at an oscillation frequency of ( _c− Δf _{1, n} −Δf _{2, n} ), and the RF signal is transmitted to the BS 2-3 (step S1306). Specifically, after a predetermined time at the start of communication, the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} is determined by the QM 14 of the branch other than the master branch of the modem 5-2 in the MS 1-3. The quadrature modulation is performed on the basis of the sine wave digital signal having the oscillation frequency. Then, the U / C 42 of the RF unit 4-2 converts the frequency into an RF signal based on the sine wave signal having the oscillation frequency of the predetermined value Lo in the local oscillator 40, and the RF signal is transmitted from the MS1-3.

  As a result, the radio frequency of the RF signal transmitted from each branch other than the master branch matches the radio frequency of the RF signal transmitted from the master branch.

MS1-3 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) for each branch, and continues demodulation processing (step S1307). Specifically, the received RF signal is frequency-converted into an IF signal by the D / C 41 of the RF unit 4-2 in the MS1-3 based on a sine wave signal having an oscillation frequency of the default value Lo in the local oscillator 40. . Then, the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) obtained by correcting the predetermined value f _c with the frequency deviation (Δf _{1, n} + Δf _{2, n} ) by the QDM 20 of the modem 5-2. The quadrature demodulation is performed on the basis of the sine wave digital signal of the oscillation frequency. That is, the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) reflecting the frequency deviation (Δf _{1, n} + Δf _{2, n} ) between MS1-3 and BS2-3 by the QDM _20. Quadrature demodulation is performed on the basis of a sine wave digital signal having an oscillation frequency of.

However, the frequency deviation (Δf _{1, n} + Δf _{2, n} ) detected in each branch of the modem unit 5-2 in the MS1-3 is the frequency deviation (Δf) in each branch of the modem unit 8-2 in the BS2-3. _{1, m} + Δf _{2, m} ) is corrected, so that it is ideally close to zero. That is, the frequency deviation (Δf _{1, n} + Δf _{2, n} ) detected in each branch other than the master branch of the modem unit 5-2 in the MS 1-3 is equivalent to the frequency deviation between the master branch and each branch. To do.

  In this process, the process proceeds from step S1306 and step S1307 to step S1302, and steps S1302 to S1307 are repeated.

FIG. 14 is a diagram for explaining the radio frequency of the process shown in FIG. The radio frequency of the RF signal transmitted from the master branch of the MS1-3 and f _1, the radio frequency of the RF signal transmitted from the branch other than the master branch of the MS1-3 and f _{1, n,} BS1-3 of m The radio frequency of the RF signal transmitted from the th branch is assumed to be f2 _{, m} . Hereinafter, “−m” and “−n” added to the component numbers indicate the components of the m-th and n-th branches, respectively.

The upper part of FIG. 14 corresponds to Example 2 shown in FIG. When an RF signal having a radio frequency f ₁ is transmitted from the master branch of the MS 1-3 at the start of communication, the radio frequency f _{2, m} of the RF signal transmitted from the m-th branch of the BS 2-3 has a frequency deviation ( Δf _{1, m} + Δf _{2, m} ) changes to the corrected frequency, and as a result, naturally matches the radio frequency f ₁ of the RF signal transmitted from the master branch of MS1-3.

Referring to the lower part of FIG. 14, in the master branch of MS1-3, by QM14-1, quadrature modulation is performed on the basis of the sine-wave digital signal of the oscillation frequency of the default values f _c, the master branch of MS1-3 In other branches, quadrature modulation is performed by the QM 14-n based on the sine wave digital signal having the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ). Since the radio frequency f _{2, m} of the RF signal received by the MS 1-3 from the BS 2-3 matches the radio frequency f ₁ as shown in the upper part of FIG. 14, it is transmitted from a branch other than the master branch of the MS 1-3. The radio frequency f _{2, n of the} RF signal is also corrected so as to coincide with the radio frequency f _{2, m} = f ₁ of BS2-3.

As a result, the radio frequency f _{2, n} of the RF signal transmitted from a branch other than the master branch of MS1-3 changes to a frequency in which the frequency deviation (Δf _{1, n} + Δf _{2, n} ) is corrected, and as a result. Therefore, it naturally matches the radio frequency f ₁ of the RF signal transmitted from the master branch of MS1-3.

As described above, according to the wireless communication system of the third embodiment, each branch of MS1-3 uses an independent local oscillator 40, and each branch of BS2-3 uses an independent local oscillator 70. If the master branch of MS1-3 are orthogonal modulated transmission signal at the oscillation frequency of the default values f _c, and frequency conversion of a transmission signal at the oscillation frequency of the default Lo in the local oscillator 40 of the branch, the reference An RF signal having a radio frequency to be transmitted is transmitted. Also, branches other than the master branch of MS1-3 are not allowed to transmit an RF signal within a predetermined time at the start of communication, and after a predetermined time, the frequency deviation (Δf _{1, n} + Δf _2, detected by the branch) is determined _{. n} ) At the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) reflecting _n ), the quadrature modulation is performed and the RF signal is transmitted, and the quadrature demodulation is performed.

Each branch of BS2-3 detects a frequency deviation (Δf1 _{, m} + Δf2 _{, m} ) reflecting a frequency deviation between local oscillator 40 of MS1-3 and local oscillator 70 of the branch of BS2-3. Then, at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ), quadrature modulation is performed and an RF signal is transmitted, and quadrature demodulation is performed.

  Thus, within a predetermined time at the start of communication, the radio frequency of the RF signal transmitted from each branch of BS2-3 is matched with the reference radio frequency of the RF signal transmitted from the master branch of MS1-3. Can do. That is, a state in which there is a radio frequency deviation between the master branch of MS1-3 and each branch of BS2-3 changes to a state in which there is no radio frequency deviation, and wireless communication is performed between the branches of BS2-3. The state changes from the state where the frequency deviation exists to the state where the radio frequency deviation does not exist.

  The branches other than the master branch of the MS1-3 receive the RF signal of the reference radio frequency from each branch of the BS2-3, and transmit the RF signal of the reference radio frequency after a predetermined time. Thereby, the radio frequency of the RF signal transmitted from a branch other than the master branch of MS1-3 can be matched with the reference radio frequency of the RF signal transmitted from the master branch of MS1-3. In other words, the state changes from a state where there is a radio frequency deviation between the branches of MS1-3 to a state where there is no radio frequency deviation between the branches of MS1-3. As a result, the radio frequencies of all RF signals transmitted from the MS1-3 and BS2-3 match.

  Therefore, the radio frequency of the RF signal transmitted from the RF unit 4-2 of the MS1-3 is transmitted from the RF unit 7-2 of the BS2-3 within the radio communication system without using an external reference signal. It is possible to match the radio frequency of the RF signal to be made with high accuracy.

Example 4
Next, Example 4 will be described. The fourth embodiment is an application example of the third embodiment in which each branch of the MS uses an independent local oscillator and each branch of the BS also uses an independent local oscillator. The master branch is updated when it becomes unusable due to the above. Hereinafter, in the fourth embodiment, the description of the same components as those in the third embodiment is omitted.

(MS1-4 / Example 4)
MS1-4 in the radio | wireless communications system of Example 4 is demonstrated in detail. FIG. 15 is a block diagram showing the configuration of MS1-4. The MS1-4 includes an antenna 3, a switch 55, an RF unit 4-2, a modem unit 5-3, and a master selection unit 16 common to all branches.

  Similarly to MS1-3 of the third embodiment illustrated in FIG. 12, the lower stage of MS1-4 illustrated in FIG. 15 is a transmission processing block unit, and the upper stage is a reception processing block unit. The transmission processing block unit is the same as that of the third embodiment, and the reception processing block unit includes the D / C 41 of the RF unit 4-2, the A / D conversion unit 51 of the modulation / demodulation unit 5-3, the QDM 20,. The adder 30 is further provided with an NCO 31 ′ and a switch 38 ′ different from those of the third embodiment, and a master selector 16 common to all branches.

(RF section 4-2)
The RF section 4-2 shown in FIG. 15 is the same as the RF section 4-2 of the third embodiment shown in FIG.

(Modem 5-3)
The modulation / demodulation unit 5-3 includes a transmission processing unit shown in the lower stage and a reception processing unit shown in the upper stage in the configuration of one branch. When the MS 1-4 does not receive a signal of a master branch NG described later from the BS 2-4, the modem unit 5-3 operates in the same manner as in the third embodiment. Similar to the third embodiment, the transmission processing unit includes an IFFT calculation unit 10 and the like.

The QM 14 of the modem unit 5-3 is the same as that of the third embodiment. Incidentally, the master selection unit 16 to be described later, when a new master branch is selected, QM14 new master branch of the modem unit 5-3, the switch 38 ', the oscillation frequency of the default f _c sine Rather than inputting a wave digital signal, the latest correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} when operating as a normal branch before a new master branch is selected) ) Is input and a quadrature modulation is performed. Thereafter, the QM 14 of the new master branch inputs this sine wave digital signal in a fixed manner.

Thus, if the master branch of the start of communication is continuously selected, the communication starting master branch, quadrature modulated RF signal at an oscillation frequency of the default values f _c is sent, the radio of the RF signal Frequency is the reference. After that, when the master branch becomes unusable due to a failure, etc., and a new master branch is selected, the latest from when the new master branch was operating as a normal branch before the new master branch was selected An RF signal that is quadrature modulated at the oscillation frequency of the correction value f _NCO (= f _c −Δf _{1, n} −Δf _{2, n} ) is transmitted. The radio frequency of this RF signal is the reference. That is, immediately after switching from the old master branch to the new master branch, the radio frequency of the RF signal transmitted from the new master branch is the same as the radio frequency of the RF signal transmitted from the old master branch immediately before switching. . Thereafter, when the radio frequency of the RF signal transmitted from the new master branch fluctuates, the radio frequency of the RF signal transmitted from the other branch follows the fluctuating radio frequency.

Thus, communication start after, the master branch of MS1-4, is quadrature-modulated by the oscillation frequency of the default values f _c of the fixed and the frequency-converted RF signal by the oscillation frequency of the fixed default value Lo (fixed RF signal) of the radio frequency _{f 1} is always transmitted. In addition, the RF signal is not transmitted from a branch other than the master branch of the MS1-4 within a predetermined time at the start of communication, and the correction value (f _NCO = f _c −Δf _{1, n} −Δf _2, after the predetermined time elapses) _. An RF signal that is orthogonally modulated at the oscillation frequency of _n ) and frequency-converted at the oscillation frequency of a fixed default value Lo is transmitted. After that, when the master branch becomes unusable due to a failure or the like, and a new master branch is selected, it operates as a normal branch before the new master branch is selected from the new master branch of MS1-4. The latest correction value f _NCO (= f _c −Δf _{1, n} −Δf _{2, n} ) was orthogonally modulated at the oscillation frequency and frequency conversion was performed at the fixed default value Lo. An RF signal is transmitted.

  The reception processing unit includes an A / D conversion unit 51, a QDM 20,. NCO 31 'and switch 38'). Since the components other than the NCO 31 'and the switch 38' are the same as those in the third embodiment shown in FIG. 12, the description thereof is omitted here.

The NCO 31 ′ receives the frequency deviation (Δf _{1, n} + Δf _{2, n} ) from the adder 30 and also receives a selection signal from the master selection unit 16 described later, and the selection signal is a normal branch (a branch other than the master branch). ), The latest frequency deviation (Δf _{1, n} + Δf _{2, n} ) when operating as a normal branch is stored in a memory (not shown), and processing similar to that of the NCO 31 of the third embodiment is performed. I do. When the NCO 31 ′ determines that the normal branch is switched to the master branch based on the selection signal, the latest frequency deviation (Δf _{1, n} + Δf ₂ when operating as the normal branch from the memory is determined. _{, n} ), and outputs a sine wave digital signal having the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) to the switch 38 ′, and causes the QM 14 to perform modulation processing. In this case, the NCO 31 ′ outputs a sine wave digital signal having an oscillation frequency of the correction value f _NCO (= f _c −Δf _{1, n} −Δf _{2, n} ) calculated (updated) at that time to the QDM 20 for demodulation. Let the process do.

Switch 38 ', as well as from the oscillator 50 inputs a sinusoidal digital signal of the oscillation frequency of the default values f _c, NCO 31' correction value f _NCO from _{(= f c -Δf 1, n} -Δf 2, n) the oscillation frequency of the The sine wave digital signal is input, and further, a selection signal is input from the master selection unit 16 described later. Switch 38 'outputs if the selection signal indicates master branch at the start communications, the sine-wave digital signal of the oscillation frequency of the default values f _c from the oscillator 50 to QM14. When the selection signal indicates a normal branch, the switch 38 ′ does not output any sine wave digital signal to the QM 14 within a predetermined time at the start of communication, and after a predetermined time, the correction value f from the NCO 31 ′. A sine wave digital signal having an oscillation frequency of _NCO (= f _c −Δf _{1, n} −Δf _{2, n} ) is output to the QM 14. When the switch 38 ′ determines that the normal branch is switched to the master branch based on the selection signal, the correction value f _NCO (= f _c −Δf _{1, n} −Δf _{2, n} ) from the _NCO 31 ′ is obtained. A sine wave digital signal having an oscillation frequency (correction value f _NCO (= f _c −Δf _{1, n} −Δf for correcting the latest frequency deviation (Δf _{1, n} + Δf _{2, n} ) when operating as a normal branch) _{2, n} ) is output to the QM14.

(Master selection unit 16)
The master selection unit 16 selects a master branch from a plurality of branches, and outputs a selection signal indicating a master branch or a selection signal indicating a normal branch to the NCO 31 ′ and the switch 38 ′ of each branch. In addition, the master selection unit 16 receives the frequency domain reception signal from the FFT calculation unit 34, performs OFDM demodulation on the reception signal, and determines whether or not the reception signal includes the signal of the master branch NG. When the master selection unit 16 determines that the signal of the master branch NG is included, the master selection unit 16 selects a new master branch and sends a selection signal indicating the new master branch to the NCO 31 ′ and the switch 38 ′ of the new master branch. Output to. Further, the master selection unit 16 outputs a selection signal indicating a normal branch to the NCO 31 ′ and the switch 38 ′ of branches other than the new master branch.

  Note that the master selection unit 16 may determine that a branch operating as a normal branch is switched to the master branch based on the signal of the master branch NG. In this case, the master selection unit 16 outputs a selection signal indicating that the normal branch has been switched to the master branch to the NCO 31 'and the switch 38'. In FIG. 15, the master selection unit 16 is provided outside the modem unit 5-3, but may be provided inside the modem unit 5-3.

(BS2-4 / Example 4)
The BS 2-4 in the wireless communication system according to the fourth embodiment will be described in detail. FIG. 16 is a block diagram showing a configuration of BS 2-4. The BS 2-4 includes an antenna 6, a switch 60, an RF unit 7-2, a modem unit 8-3, and a master transmission determination unit 18 common to all branches.

  Similarly to the BS 2-2 of the second embodiment illustrated in FIG. 8, the lower stage of the BS 2-4 illustrated in FIG. 16 is a transmission processing block unit, and the upper stage is a reception processing block unit. The transmission processing block unit is the same as that of the second embodiment, and the reception processing block unit is different from the second embodiment in that it includes a master transmission determination unit 18 that is common to all branches.

(RF unit 7-2)
Since the RF unit 7-2 shown in FIG. 16 is the same as the RF unit 7-2 of the second embodiment shown in FIG. 8, the description thereof is omitted here.

(Modulator / Demodulator 8-3)
The modem unit 8-3 shown in FIG. 16 is the same as the modem unit 8-2 of the second embodiment shown in FIG.

(Master transmission determination unit 18)
Master transmission determination unit 18 receives the frequency domain received signal from FFT operation unit 106, detects the pilot carrier of each branch of MS1-4, and whether the amplitude level of the pilot carrier of each branch is equal to or greater than a predetermined threshold value. Determine whether or not. When the master transmission determination unit 18 determines that the amplitude level of the pilot carrier of each branch is equal to or greater than a predetermined threshold, the master transmission determination unit 18 determines that the RF signal is normally transmitted from each branch of the MS1-4. On the other hand, when the master transmission determination unit 18 determines that the amplitude level of the pilot carrier of each branch is not equal to or higher than the predetermined threshold (less than the predetermined threshold), the RF signal is normally transmitted from the corresponding branch of MS1-4. Judge that it is not.

  When the master transmission determination unit 18 determines that the amplitude level of the pilot carrier of the master branch is equal to or greater than a predetermined threshold, the master transmission determination unit 18 determines that the RF signal is normally transmitted from the master branch and is usable, and the master branch is An OK signal indicating that it can be used is output to a transmission signal generator (not shown). On the other hand, if the master transmission determination unit 18 determines that the amplitude level of the pilot carrier of the master branch is not equal to or higher than the predetermined threshold (less than the predetermined threshold), the master branch is not transmitting the RF signal normally and is used. It judges that it is impossible, and outputs the NG signal which shows that a master branch is unusable to the transmission signal generation part which is not illustrated. This NG signal is inserted into the transmission signal as a master branch NG signal and transmitted from the BS 2-4.

  A transmission signal generation unit (not shown) inputs an OK signal / NG signal from the master transmission determination unit 18 and, when an NG signal is input, generates a transmission signal by inserting the signal of the master branch NG into a header or the like, It outputs to the IFFT calculating part 85 as a modulation signal after mapping. Thereby, the RF signal including the signal of the master branch NG is transmitted from the BS 2-4.

  In FIG. 16, the master transmission determining unit 18 is provided outside the modem unit 8-3, but may be provided inside the modem unit 8-3.

(Frequency deviation correction processing / Example 4)
Next, in the wireless communication system according to the fourth embodiment, the radio frequency of the RF signal transmitted from each branch of the RF unit 4-2 of the MS1-4 and each branch of the RF unit 7-2 of the BS2-4 are transmitted. A process for correcting the deviation of the RF signal from the radio frequency to match the radio frequencies of all paths will be described.

FIG. 17 is a flowchart illustrating processing for correcting and matching radio frequency deviations in the fourth embodiment. First, the MS 1-4 transmits an RF signal from a master branch (for example, the first branch) (step S1701). The BS 2-4 detects the frequency deviation (Δf _{1, m} + Δf _{2, m} ) between the master branch of the MS 1-4 and the branch of the BS 2-4 for each branch (step S1702). Steps S1701 and S1702 are the same as steps S1301 and S1302 shown in FIG.

  The BS 2-4 determines whether the transmission by the master branch of the MS 1-4 is normal (OK) or not (step S1703), and the communication is normal (the master branch is usable). (Step S1703: Y), the process proceeds to step S1704 and step S1705. On the other hand, if the BS 2-4 determines that the communication is not normal (abnormal, the master branch is unusable) (step S1703: N), the BS 2-4 proceeds to step S1709. The process of step S1703 is performed by the master transmission determination unit 18.

When the communication of the master branch is normal, the BS 2-4 proceeds from step S1703, and the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) is set for each branch. The transmission signal is orthogonally modulated and the RF signal is transmitted to MS1-4 (step S1704). The BS 2-4 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) for each branch, and continues the demodulation process (step S1705). ).

MS1-4 detects the frequency deviation (Δf _{1, n} + Δf _{2, n} ) between MS1-4 and BS2-4 for each branch (step S1706). Then, MS1-4, in master branch, orthogonally modulates the transmission signal at the oscillation frequency of the default values f _c, and transmits the RF signal to BS2-4, the branch other than the master branch correction value (f _NCO = F _c −Δf _{1, n} −Δf _{2, n} ), the transmission signal is quadrature modulated and the RF signal is transmitted to BS 2-4 (step S1707). Further, MS1-4 performs quadrature demodulation of the received signal at the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, n} −Δf _{2, n} ) for each branch, and continues the demodulation process (step S1708). ). Steps S1704 to S1708 are the same as steps S1303 to S1307 shown in FIG.

  If the master branch communication is not normal in step S1703, the BS 2-4 proceeds from step S1703 and transmits a signal of the master branch NG to the MS1-4 (step S1709).

Upon receiving the signal of the master branch NG, the MS 1-4 selects a new master branch, and in the new master branch, the normal correction value (f) before the communication of the previous master branch becomes abnormal (NG). _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) is orthogonally modulated with a fixed oscillation frequency, and an RF signal is transmitted to MS1-4. Further, MS1-4 performs quadrature modulation with the updated oscillation frequency in the branch other than the new master branch, and transmits the RF signal to BS2-4 (step S1710).

In this process, the process proceeds from step S1707, step S1708, and step S1710 to step S1702, and steps S1702 to S1710 are repeated. Note that, after receiving the signal of the master branch NG and selecting a new master branch, the MS 1-4 receives the same correction value as in step S1710 in the new master branch in step S1707 (the communication of the previous master branch is Quadrature modulation is performed with the oscillation frequency of the correction value (f _NCO = f _c −Δf _{1, m} −Δf _{2, m} ) in the normal state before becoming abnormal (NG) as a fixed oscillation frequency, and the RF signal is MS1-4 Send to.

  As described above, according to the wireless communication system of the fourth embodiment, each branch of MS1-4 uses an independent local oscillator 40, and each branch of BS2-4 also uses an independent local oscillator 70. In this case, as in the third embodiment, when one of the plurality of branches of the MS1-4 is operating as a master branch, the master transmission determination unit 18 of the BS2-4 Is determined to be not greater than or equal to a predetermined threshold (less than the threshold), it is determined that the master branch is unusable, and the BS 2-4 transmits an RF signal including the signal of the master branch NG.

When determining that the RF signal from the BS 2-4 includes the signal of the master branch NG, the master selection unit 16 of the MS 1-4 selects a new master branch. New master branch of MS1-4 the latest frequency deviation _{(Δf 1, n + Δf 2} , n) the correction value f _NCO reflecting the (= f _c -Δf _{1, n} when operating as a normal branch Quadrature modulation is performed with an oscillation frequency of −Δf _{2, n} ) as a fixed oscillation frequency, and an RF signal is transmitted.

  As a result, when the master branch becomes unusable due to a device failure or the like and a new master branch is selected, immediately after switching from the old master branch to the new master branch, the RF signal transmitted from the new master branch The radio frequency is the same as the radio frequency of the RF signal transmitted from the old master branch immediately before switching. Thereafter, when the radio frequency of the RF signal transmitted from the new master branch fluctuates, the radio frequency of the RF signal transmitted from the other branch follows the fluctuating radio frequency.

  That is, the radio frequency of the RF signal transmitted from a branch other than the new master branch of MS1-4 can be matched with the radio frequency of the RF signal transmitted from the new master branch of MS1-4. As a result, the radio frequencies of all RF signals transmitted from MS1-4 and BS2-4 match.

  Therefore, even when the master branch becomes unusable due to a device failure or the like, it is transmitted from the RF unit 4-2 of the MS1-4 within the wireless communication system without using an external reference signal. It is possible to match the radio frequency of the RF signal transmitted from the RF unit 7-2 of the BS 2-4 with the radio frequency of the RF signal with high accuracy.

  Although the present invention has been described with reference to the first to fourth embodiments, the present invention is not limited to the first to fourth embodiments, and various modifications can be made without departing from the technical idea thereof. In the first to fourth embodiments, the example of the wireless communication system by MIMO-OFDM using the four antennas 3 and the four antennas 6 has been described. However, the number of the antennas 3 and the antennas 6 is limited to four each. It is not a thing.

  In the first embodiment, each branch of the MS 1-1 uses a common local oscillator 40, and each branch of the BS 1-1 uses a common local oscillator 70. In the second embodiment, the MS 1-2 is In this example, each branch of BS2-2 uses a separate local oscillator 70, and each branch of BS2-2 uses an independent local oscillator 70. In the third and fourth embodiments, each branch of MS1-3 and 1-4 is This is an example in which an independent individual local oscillator 40 is used and each branch of BS2-3 and 2-4 is also used as an independent local oscillator 70. The present invention is also applicable to the case where each branch of the MS uses an independent local oscillator 40 and each branch of the BS uses a common local oscillator 70.

  In the MSs 1-1 to 1-4 of the first to fourth embodiments, each configuration of the signal processing units 53 and 113 (and the master selection unit 16 in the fourth embodiment) included in the modem units 5-1 to 5-3. The processing of the unit may be realized by an LSI chip which is an integrated circuit mounted on the MS 1-1 to 1-4, and includes an A / D conversion unit 51 and a D / A conversion unit 52. The processing of each component may be realized by an LSI chip. These may be individually made into one chip, or a part or all of them may be made into one chip.

  Further, in the BSs 2-1 to 2-4 of the first to fourth embodiments, each of the signal processing units 83 and 112 (and the master transmission determining unit 18 in the fourth embodiment) included in the modem units 8-1 to 8-3. The processing of the constituent units may be realized by an LSI chip that is an integrated circuit mounted on the BS 2-1 to 2-4, and an A / D conversion unit 81 and a D / A conversion unit 82 are added thereto. The processing of each component included may be realized by an LSI chip. These may be individually made into one chip, or a part or all of them may be made into one chip.

  Further, instead of the LSI, it may be realized by a chip such as a VLSI or ULSI having a different degree of integration. Furthermore, the present invention is not limited to a chip such as an LSI, and a dedicated circuit or a general-purpose processor may be used, or an FPGA (Field Programmable Gate Array) may be used.

1,110 MS
2,200 BS
3, 6, 111, 201 Antenna 4, 7, 202 Transmission / reception high-frequency unit (RF unit)
5, 8, 203 Modulator / Demodulator 10, 85 Inverse Fast Fourier Transform Operation Unit (IFFT Operation Unit)
11,86 GI addition unit 12,87 Upsampling unit (US)
13, 21, 88, 93 Low-pass filter (LPF)
14,89 Quadrature modulation unit (QM)
16 Master selection unit 18 Master transmission determination unit 20, 92 Quadrature demodulation unit (QDM)
22,94 Downsampling unit (DS)
23, 95 Preamble storage unit 24, 96 Mobile correlation unit 25, 97 Correlation peak detection unit 26, 98 Frame synchronization detection unit 27, 99 Trigger signal generation unit 28, 100 First frequency deviation detection unit 29, 101 Frequency deviation storage unit 30,102 Adder 31,103 Numerically controlled oscillator (NCO)
32, 104 Symbol synchronization detection unit 33, 105 FFT window timing unit 34, 106 Fast Fourier transform operation unit (FFT operation unit)
35, 107 Pilot carrier extraction unit 36, 108 Second frequency deviation detection unit 37, 109 Reset signal generation unit 38, 55, 60 Switch 40, 70 Local oscillator 41, 71 Down converter (D / C)
42,72 Upconverter (U / C)
50, 80 Oscillator 51, 81 Analog-digital converter (A / D converter)
52,82 Digital / analog converter (D / A converter)
53, 83, 112, 113 Signal processing unit 54, 84 Average unit 204 Optical fiber

Claims (4)

A transmission signal is modulated to transmit a radio frequency band signal (RF signal), and a radio communication device on the mobile station side having a plurality of branches that receive and demodulate the RF signal, and the transmission signal to modulate the RF And a base station-side radio communication device having a plurality of branches that receive and demodulate an RF signal and transmit the signal, and the mobile station-side radio communication device and the base station by a time division duplex method In the wireless communication device on the mobile station side in the wireless communication system by MIMO-OFDM that performs one-to-one bidirectional communication with the wireless communication device on the side,
A transmission / reception high-frequency unit (RF unit) and a modulation / demodulation unit corresponding to each of the plurality of branches, and a mobile station side local oscillator and a first oscillator common to the plurality of branches,
The mobile station side local oscillator is
Output a signal with the default oscillation frequency,
The first oscillator is
Output the first sine wave digital signal with the default oscillation frequency,
The RF unit is
Based on the signal output from the mobile station-side local oscillator, the frequency of the received RF signal is converted, and a down converter that outputs the received signal as a received signal;
Based on the signal output from the mobile station-side local oscillator, the frequency of the orthogonally modulated transmission signal from the modulation / demodulation unit is converted and output as an RF signal transmitted by the mobile station-side radio communication device And comprising
The modem unit is
A frequency deviation detector for detecting a deviation in oscillation frequency between the mobile station side local oscillator and a base station side local oscillator provided in the base station side radio communication device, and outputting as a frequency deviation;
The first sine wave digital signal output by the first oscillator is input , and an average frequency deviation that is an average value of the frequency deviations in the plurality of branches is input, and the oscillation frequency of the first sine wave digital signal is input. Subtracting the average frequency deviation from the second oscillator to generate a second sine wave digital signal for correcting the average frequency deviation;
Based on a second sine wave digital signal generated by the second oscillator, an orthogonal demodulation unit that orthogonally demodulates the reception signal output by the down converter of the RF unit;
Based on a first sine wave digital signal output by the first oscillator, an orthogonal modulation unit that orthogonally modulates the transmission signal;
Each of the frequency deviations output by the frequency deviation detectors in the modems of the plurality of branches is input, and the average frequency deviation that is an average value in the plurality of branches is calculated from the frequency deviations of the plurality of branches, An average unit that outputs an average frequency deviation ,
Using the RF signal output from the up-converter as a reference signal, the base station side transmits a fixed radio frequency of each of the RF signals transmitted by a plurality of branches provided in the mobile station side radio communication apparatus. A radio communication apparatus on a mobile station side, wherein radio frequencies of the respective RF signals transmitted by a plurality of branches provided in the radio communication apparatus are matched . A radio communication device on the mobile station side according to claim 1 and a plurality of branches for receiving and demodulating an RF signal transmitted from the radio communication device on the mobile station side while modulating a transmission signal and transmitting an RF signal. The base station side wireless communication device is provided, and performs one-to-one bidirectional communication between the mobile station side wireless communication device and the base station side wireless communication device by a time division duplex method. In the radio communication device on the base station side in the radio communication system based on MIMO-OFDM,
A transmission / reception high-frequency unit ( RF unit ) and a modulation / demodulation unit corresponding to each of the plurality of branches, and a base station side local oscillator and a first oscillator common to the plurality of branches,
The base station side local oscillator is:
Output a signal with the default oscillation frequency,
The first oscillator is
Output the first sine wave digital signal with the default oscillation frequency,
The RF unit is
Based on the signal output by the base station side local oscillator, the frequency of the received RF signal is converted, and a down converter that outputs the received signal,
Based on the signal output from the base station side local oscillator, the frequency of the orthogonally modulated transmission signal from the modulation / demodulation unit is converted and output as an RF signal transmitted by the base station side wireless communication device And comprising
The modem unit is
A frequency deviation detector that detects a deviation of an oscillation frequency between the base station side local oscillator and the mobile station side local oscillator provided in the mobile station side radio communication device, and outputs the frequency deviation;
The first sine wave digital signal output by the first oscillator is input , and an average frequency deviation that is an average value of the frequency deviations in the plurality of branches is input, and the oscillation frequency of the first sine wave digital signal is input. Subtracting the average frequency deviation from the second oscillator to generate a second sine wave digital signal for correcting the average frequency deviation;
Based on a second sine wave digital signal generated by the second oscillator, an orthogonal demodulation unit that orthogonally demodulates the reception signal output by the down converter of the RF unit;
Based on a second sine wave digital signal generated by the second oscillator, an orthogonal modulation unit that orthogonally modulates the transmission signal;
Each of the frequency deviations output by the frequency deviation detectors in the modems of the plurality of branches is input, and the average frequency deviation that is an average value in the plurality of branches is calculated from the frequency deviations of the plurality of branches, An average unit that outputs an average frequency deviation ,
The RF signal output by the up-converter of the RF unit provided in the mobile station side radio communication device, the radio frequency of each RF signal transmitted by the plurality of branches provided in the base station side radio communication device. The base station-side radio communication apparatus is configured to match a fixed radio frequency of each of the RF signals transmitted by a plurality of branches provided in the mobile station-side radio communication apparatus with reference signal as a reference signal . A radio communication device on the mobile station side according to claim 1 and a plurality of branches for receiving and demodulating an RF signal transmitted from the radio communication device on the mobile station side while modulating a transmission signal and transmitting an RF signal. The base station side wireless communication device is provided, and performs one-to-one bidirectional communication between the mobile station side wireless communication device and the base station side wireless communication device by a time division duplex method. In the radio communication device on the base station side in the radio communication system based on MIMO-OFDM,
A base station side local oscillator corresponding to each of the plurality of branches , a transmission / reception high-frequency unit ( RF unit ) and a modem unit , and a first oscillator common to the plurality of branches ,
The base station side local oscillator is:
Output a signal with the default oscillation frequency,
The first oscillator is
Output the first sine wave digital signal with the default oscillation frequency,
The RF unit is
A down-converter on the basis of the previous SL base station local oscillator by an output signal, converts the frequency of the RF signal received, and outputs as a reception signal,
Based on the signal output from the base station side local oscillator, the frequency of the orthogonally modulated transmission signal from the modulation / demodulation unit is converted and output as an RF signal transmitted by the base station side wireless communication device And comprising
The modem unit is
Detecting a deviation of the oscillation frequency between the mobile station side local oscillator provided in the wireless communication device prior SL base station-side local oscillator and the mobile station side, the frequency deviation detecting unit for outputting a frequency deviation,
The first sine wave digital signal output by the first oscillator and the frequency deviation output by the frequency deviation detector are input, and the frequency deviation is calculated from the oscillation frequency of the first sine wave digital signal. A second oscillator for generating a second sine wave digital signal for subtracting and correcting the frequency deviation;
Based on a second sine wave digital signal generated by the second oscillator, an orthogonal demodulation unit that orthogonally demodulates the reception signal output by the down converter of the RF unit;
An orthogonal modulation unit that orthogonally modulates the transmission signal based on the second sine wave digital signal generated by the second oscillator ;
The RF signal output by the up-converter of the RF unit provided in the mobile station side radio communication device, the radio frequency of each RF signal transmitted by the plurality of branches provided in the base station side radio communication device. The base station-side radio communication apparatus is configured to match a fixed radio frequency of each of the RF signals transmitted by a plurality of branches provided in the mobile station-side radio communication apparatus with reference signal as a reference signal . In the radio | wireless communication apparatus as described in any one of Claim 1 to 3 ,
In the time division duplex method, transmit / receive an RF signal of a subframe including a preamble for causing another wireless communication device to detect a frequency deviation,
The frequency deviation detector is
A fast Fourier transform of the received signal demodulated by the orthogonal demodulator to generate a signal in the frequency domain;
A first frequency deviation detection unit that detects a first frequency deviation using a preamble included in a subframe of a reception signal that is orthogonally demodulated by the orthogonal demodulation unit;
A pilot carrier extraction unit that extracts a pilot carrier from a frequency domain signal generated by the fast Fourier transform calculation unit;
A second frequency deviation detector that detects a second frequency deviation using the pilot carrier extracted by the pilot carrier extractor;
The first frequency deviation detected by the first frequency deviation detector and the second frequency deviation detected by the second frequency deviation detector are added, and the addition result is output as the frequency deviation. An adder;
A wireless communication apparatus comprising:

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