JP5650939B2 - Radio base station and communication control method - Google Patents

Description

  The present invention relates to a radio base station that transmits and receives radio signals to and from a radio terminal using a plurality of antennas, and a communication control method in the radio base station.

  In 3GPP (Third Generation Partnership Project), in a wireless communication system corresponding to LTE (Long Term Evolution) currently being developed, the wireless base station eNB is wireless in wireless communication with the wireless base station eNB wireless terminal UE. Resources are allocated (see, for example, Non-Patent Document 1). Moreover, in the radio | wireless communications system corresponding to LTE, frequency division duplex (FDD: Firequency Division Duplex) and time division duplex (TDD: Time Division Duplex) are used for radio | wireless communication between the radio base stations eNB radio | wireless terminal UE. Is adopted.

  Furthermore, in an LTE (TDD-LTE) radio communication system employing TDD, the radio base station eNB transmits a downlink radio signal in order to ensure communication quality between the radio base station eNB and the moving radio terminal UE. It has been studied to perform control (adaptive array control) in which a beam is adaptively directed to the direction of the radio terminal UE during transmission.

3GPP TR 36.211 V8.7.0 “Physical Channels and Moduration”, MAY 2009

  For example, in the next generation PHS (XGP) radio communication system, the frequency band for the downlink radio signal allocated to the radio terminal is the same as the frequency band for the uplink radio signal. For this reason, the radio base station can detect the downlink of the same frequency band as the uplink radio signal based on the propagation environment of the uplink radio signal frequency band, which is grasped by the uplink radio signal from the radio terminal. The antenna weight for the radio signal can be calculated.

  On the other hand, in the TDD-LTE radio communication system, OFDMA (Orthogonal Frequency Division Multiplexing Access) is adopted for downlink radio communication, and SC-FDMA (Single Carrier Frequency Division Multiple Access) is adopted for uplink radio communication. Has been. These multiplexing schemes implement user multiplexing by arranging radio resources in two dimensions of frequency and time, and the frequency band for the downlink radio signal allocated to the radio terminal UE and the uplink radio signal The frequency band may not be the same.

  Therefore, when the radio base station eNB receives an uplink radio signal from the radio terminal UE, the radio base station eNB has the same frequency band as the uplink radio signal based on the propagation environment of the frequency band for the uplink radio signal. It is not always possible to calculate antenna weights for downlink radio signals.

  In view of the above-described problems, an object of the present invention is to provide a radio base station and a communication control method that enable appropriate adaptive array control.

In order to solve the above-described problems, the present invention has the following features. The first feature of the present invention is that a plurality of antennas (adaptive array antenna 108A, adaptive array antenna 108B, adaptive array antenna 108C, adaptive array antenna 108D) are used to transmit a radio signal to a radio terminal (radio terminal UE2). Is an adaptive array radio base station (radio base station eNB1) that transmits and receives an antenna weight for each frequency band based on each of reference signals for a plurality of frequency bands in an uplink radio signal. A calculating unit (AAS processing unit 126) for calculating, an allocating unit (RB allocating unit 120) for allocating a frequency band used for a downlink radio signal, and a setting unit for setting an antenna weight for the frequency band used for the downlink radio signal (AAS setting unit 136), and the assigning unit includes The frequency band closer to the frequency band for which the antenna weight is calculated by the output unit is given higher priority when being assigned as the frequency band used for the downlink radio signal, and the setting unit is calculated by the calculation unit. Among the antenna weights, the corresponding frequency band is assigned by the assigning unit the antenna weight corresponding to the frequency band closest to the frequency band used for the downlink radio signal assigned by the assigning unit. A setting is made for a frequency band used for a downlink radio signal, and the setting unit has a frequency difference between the frequency band for which the antenna weight is calculated and a frequency band used for the downlink radio signal equal to or greater than a predetermined value. If it is, with respect to the frequency band used for the radio signals of the downlink, wherein the frequency band antenna weights are calculated And gist not to set the antenna weight, which is the calculation definitive.

  According to such a feature, the radio base station calculates an antenna weight for each frequency band based on each of the reference signals for each of the plurality of frequency bands in the uplink radio signal, and uses the frequency used for the downlink radio signal. When assigning bands, the frequency band closer to the frequency band for which the antenna weight is calculated has a higher priority for assignment. Therefore, the frequency band used for the downlink radio signal can be as close as possible to the frequency band for which the antenna weight is calculated, and the propagation environment of the frequency band for which the antenna weight is calculated and the frequency band used for the downlink radio signal To the propagation environment. For this reason, even if the calculated antenna weight is set to the frequency band used for the downlink radio signal, the occurrence of a failure in the downlink radio communication is suppressed, and an appropriate adaptive array becomes possible.

A second feature of the present invention is that the calculation unit calculates an antenna weight for each frequency band based on each of reference signals for a plurality of frequency bands belonging to a predetermined time band in the uplink radio signal. This is the gist.

According to a third feature of the present invention, the predetermined time zone includes a first half time slot and a second half time time slot, and the calculation unit belongs to the first half time slot of the uplink radio signal. Based on the first reference signal, the antenna weight of the frequency band corresponding to the first reference signal is calculated, and the second reference signal corresponding to the time slot of the second half time slot in the uplink radio signal is calculated. Based on this, the gist is to calculate the antenna weight of the frequency band corresponding to the second reference signal.

A fourth aspect of the present invention, the setting unit may extract based rather antenna weights to each of the plurality of reference signals belonging to a predetermined frequency band in the past within a predetermined period, based on the extracted antenna weight The gist is to set an antenna weight corresponding to the predetermined frequency band.

A fifth feature of the present invention is that, when the wireless terminal has one antenna and downlink wireless communication is multi-stream communication, the setting unit is configured to transmit a downlink wireless signal corresponding to the first layer . A first antenna weight is set for the frequency band, and a second antenna weight orthogonal to the first antenna weight is set for the frequency band of the downlink radio signal corresponding to the second layer. Is the gist.

A sixth feature of the present invention is a communication control method in an adaptive array radio base station that uses a plurality of antennas to transmit and receive a radio signal to and from a radio terminal. Calculating an antenna weight for each frequency band based on each of the reference signals for each of a plurality of frequency bands; assigning a frequency band used for a downlink radio signal; and a frequency band used for a downlink radio signal A step of assigning an antenna weight with respect to a frequency band closer to the frequency band for which the antenna weight is calculated. And in the setting step, the corresponding circumference of the calculated antenna weights is set. Several bands set antenna weights corresponding to frequency bands closest to the frequency band used for the allocated downlink radio signal, for the frequency band used for the allocated downlink radio signal, In the setting step, when a frequency difference between the frequency band in which the antenna weight is calculated and a frequency band used for the downlink radio signal is equal to or greater than a predetermined value, the frequency band used for the downlink radio signal On the other hand, the gist is not to set the calculated antenna weight in the frequency band in which the antenna weight is calculated .

  According to the present invention, an antenna weight in a frequency band having a propagation environment close to a frequency band used for a downlink radio signal can be set to a frequency band used for a downlink radio signal, and an appropriate adaptive array is possible.

1 is an overall schematic configuration diagram of a wireless communication system according to an embodiment of the present invention. It is a block diagram of the radio base station which concerns on embodiment of this invention. It is a figure which shows the format of PUSCH based on embodiment of this invention. It is a block diagram of the radio | wireless terminal which concerns on embodiment of this invention. It is a sequence diagram which shows the operation | movement of the time slot allocation which concerns on embodiment of this invention. It is a figure which shows an example of the correspondence of the reception weight corresponding to PUSCH, and the transmission weight corresponding to PDSCH based on embodiment of this invention.

  Next, an embodiment of the present invention will be described with reference to the drawings. Specifically, (1) the configuration of the wireless communication system, (2) the operation of the wireless communication system, (3) the operation and effect, and (4) other embodiments will be described. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

(1) Configuration of Radio Communication System First, regarding the configuration of the radio communication system according to the embodiment of the present invention, (1.1) overall schematic configuration of radio communication system, (1.2) configuration of radio base station, (1 .3) The configuration of the wireless terminals will be described in the order.

(1.1) Overall Schematic Configuration of Radio Communication System FIG. 1 is an overall schematic configuration diagram of a radio communication system 10 according to an embodiment of the present invention.

  A wireless communication system 10 illustrated in FIG. 1 is a TDD-LTE wireless communication system. The radio communication system 10 includes a radio base station eNB1 and a radio terminal UE2. In FIG. 1, a radio base station eNB1 constitutes an E-UTRAN (Evolved-UMTS Terrestrial Radio Access Network) together with another radio base station eNB (not shown). The radio terminal UE2 exists in the cell 3 that is a communicable area provided by the radio base station eNB1. In FIG. 1, only one radio terminal UE2 is shown, but actually a plurality of radio terminals UE2 exist in the cell 3.

  Time division duplex is adopted for radio communication between the radio base station eNB1 and the radio terminal UE2, OFDMA (Orthogonal Frequency Division Multiplexing Access) for downlink radio communication, and SC for uplink radio communication. -Single carrier frequency division multiple access (FDMA) is adopted. Here, downlink means a direction from the radio base station eNB1 to the radio terminal UE2, and uplink means a direction from the radio terminal UE2 to the radio base station eNB1.

  The radio base station eNB1 allocates a resource block (RB: Resource Block) as a radio resource to the radio terminal UE2 in the cell 3.

  Resource blocks include a downlink resource block (downlink RB) used for downlink radio communication and an uplink resource block (uplink RB) used for uplink radio communication. A plurality of downlink resource blocks are arranged in the frequency direction. Similarly, a plurality of uplink resource blocks are arranged in the frequency direction.

  The downlink resource block is divided into a control information channel (PDCCH: Physical Downlink Control CHannel) for downlink control information transmission and a shared data channel (PDSCH: Physical Downlink Shared CHannel) for downlink user data transmission in the time direction. Composed.

  On the other hand, in the uplink resource block, a control information channel (PUCCH: Physical Uplink Control CHannel) for uplink control information transmission is configured at both ends of all frequency bands that can be used for uplink radio communication. A shared data channel (PUSCH: Physical Uplink Shared CHannel) for user data transmission is configured.

  When allocating resource blocks, frequency hopping in which the allocated frequency is changed according to a predetermined frequency hopping pattern is applied.

  Hereinafter, a case where radio communication is performed between the radio base station eNB1 and one radio terminal UE will be described. In the following, it is assumed that a downlink resource block and an uplink resource block are allocated to the radio terminal UE2 in the initial state.

(1.2) Configuration of Radio Base Station FIG. 2 is a configuration diagram of the radio base station eNB1. As illustrated in FIG. 2, the radio base station eNB1 is an adaptive array radio base station, and includes a control unit 102, a storage unit 103, an I / F unit 104, a radio frequency (RF) reception processing unit 105, A base band (BB) processing unit 106, an RF transmission processing unit 107, an adaptive array antenna 108A, an adaptive array antenna 108B, an adaptive array antenna 108C, and an adaptive array antenna 108D are included.

  The control unit 102 is configured by a CPU, for example, and controls various functions provided in the radio base station eNB1. The control unit 102 includes an RB allocation unit 120. The memory | storage part 103 is comprised by memory, for example, and memorize | stores the various information used for control etc. in the radio base station eNB1. The I / F unit 104 can communicate with other radio base stations eNB via the X1 interface. The I / F unit 104 can communicate with an EPC (Evolved Packet Core), specifically, an MME (Mobility Management Entity) / S-GW (Serving Gateway) via the S1 interface.

  The RF reception processing unit 105 receives an uplink radio signal in the radio frequency band from the radio terminal UE2 via the adaptive array antenna 108A to the adaptive array antenna 108D. The RF reception processing unit 105 includes a low noise amplifier (LNA) and a mixer (not shown). The RF reception processing unit 105 amplifies the received uplink radio signal in the radio frequency band and converts (down-converts) it into a baseband signal. Further, the RF reception processing unit 105 outputs the baseband signal to the BB processing unit 106.

  The BB processing unit 106 includes a memory 121, a CP (Cyclic Prefix) removal unit 122, an FFT (Fast Fourier Transform) processing unit 124, an AAS (Adaptive Array System) processing unit 126, a channel equalization unit 128, an IDFT (Inverse Discrete Fourier Transform). ) Processing unit 130, demodulation decoding unit 132, encoding modulation unit 134, AAS processing unit 136, IFFT (Inverse Fast Fourier Transform) processing unit 138, and CP adding unit 140.

  An RB allocation unit 120 in the control unit 102 acquires an allocation value (RB allocation value) of a resource block obtained by processing of a medium access control (MAC) layer in the control unit 102. This RB allocation value includes a resource block number that is identification information of a downlink resource block and an uplink resource block allocated to the radio terminal UE2. The RB allocation unit 120 outputs the RB allocation value to the AAS processing unit 126 and the AAS processing unit 136.

  CP removing section 122 removes CP (Cyclic Prefix) from the input baseband signal. The CP is a copy of the end portion of the OFDM symbol and is included in a guard interval period provided to suppress intersymbol interference caused by multipath. The FFT processing unit 124 performs a fast Fourier transform on the baseband signal from which the CP has been removed to obtain a frequency domain signal.

  The AAS processing unit 126 maximizes the signal-to-interference / noise ratio (SINR) for each adaptive array antenna 108A to adaptive array antenna 108D when receiving the uplink radio signal from the radio terminal UE2 based on the frequency domain signal. An antenna weight (reception weight) is calculated.

  FIG. 3 is a diagram illustrating a PUSCH format. As illustrated in FIG. 3, the PUSCH is configured by one subframe having a time length of 1 [ms] in the time direction. The subframe includes time zones S1 to S14. Of these time zones S1 to S14, time zones S1 to S7 constitute the first half time slot (time slot 1), and time zones S8 to S14 consist of the second half time slot (time slot 2). ). A central time zone S4 in the time slot 1 is used for transmission of a demodulation reference signal (DRS). Similarly, the central time zone S11 in the time slot 2 is used for transmission of a reference signal for demodulation. Also for PDSCH, one subframe is composed of the first half time slot (time slot 1) and the second half time slot (time slot 2).

  For the setting of the reference signal for demodulation, a Zaddoff-Chu sequence with small amplitude fluctuations in the frequency direction and the time direction is employed. The reference signal for demodulation is different for each cell, and the cross-correlation of the reference signal for demodulation between cells is designed to be small.

  Moreover, as shown in FIG. 3, PUSCH has a frequency width of 180 [kHz] in the frequency direction. The PUSCH includes twelve symbol carriers F1 to F12 having a frequency width of 15 [kHz].

  Specifically, the AAS processing unit 126 specifies the frequency band of the uplink resource block allocated to the radio terminal UE2 based on the RB allocation value. Furthermore, the AAS processing unit 126 detects a reference signal for demodulation included in a frequency domain signal corresponding to the identified frequency band of the uplink resource block. Furthermore, the AAS processing unit 126 receives reception weights of the adaptive array antennas 108A to 108D corresponding to the PUSCH frequency band in the uplink resource block allocated to the radio terminal UE2 based on the demodulation reference signal. Is calculated.

  As shown in FIG. 3, in one PUSCH, a demodulation reference signal is included in each of time slot 1 and time slot 2. Accordingly, the AAS processing unit 126 calculates two reception weights for one PUSCH frequency band. The AAS processing unit 126 stores the calculated reception weight in the memory 121 together with the corresponding frequency band information and current time information (time stamp information).

  Further, the AAS processing unit 126 outputs, to the channel equalization unit 128, a frequency domain signal corresponding to the frequency band of the uplink resource block allocated to the radio terminal UE2 among the frequency domain signals from the FFT processing unit 124. .

  The channel equalization unit 128 performs channel equalization processing on the input frequency domain signal. The IDFT processing unit 130 performs inverse discrete Fourier transform on the signal that has been subjected to channel equalization processing. The demodulation and decoding unit 132 performs demodulation and decoding processing on the signal that has been subjected to inverse discrete Fourier transform. Thereby, the data transmitted by the radio terminal UE2 is obtained. Data is output to the control unit 102.

  When the data from the control unit 102 is input, the code modulation unit 134 performs coding and modulation on the data to obtain a frequency domain signal.

  The AAS processing unit 136 sets an antenna weight (transmission weight) at the time of transmission of a downlink radio signal to the radio terminal UE2 for each adaptive array antenna 108A to adaptive array antenna 108D.

  Specifically, the AAS processing unit 136 specifies the time zone and the frequency band of the downlink resource block assigned to the radio terminal UE2 based on the RB assignment value. The PDSCH in the identified downlink resource block is a PDSCH for which a transmission weight is set.

  Next, the AAS processing unit 136 has the time indicated by the time stamp information within the past predetermined period among the reception weights stored in the memory 121 and corresponding to each adaptive array antenna 108A to adaptive array antenna 108D. Receive weight is extracted. The reception weight whose time indicated by the time stamp information is within a predetermined period in the past means a reception weight calculated within a predetermined period in the past.

  The AAS processing unit 136 specifies a reception weight whose corresponding frequency band is closest to the frequency band of the PDSCH to be set among the extracted reception weights. Further, the AAS processing unit 136 sets the reception weight for each of the specified adaptive array antennas 108A to 108D to each adaptive array antenna 108A to adaptive array antenna 108D corresponding to the frequency band of the PDSCH for which transmission weights are set. Set to the transmission weight of. The AAS processing unit 136 combines the set transmission weight and the frequency domain signal.

  Here, when there are a plurality of reception weights whose corresponding frequency bands are closest to the frequency band of the PDSCH to be set, the AAS processing unit 136 may set the average value of the plurality of reception weights as the transmission weight. . Alternatively, the AAS processing unit 136 may set the latest reception weight among the plurality of reception weights as the transmission weight.

  When the frequency difference between the frequency band corresponding to the specified reception weight and the frequency band of the PDSCH to be set is equal to or greater than a predetermined value, the AAS processing unit 136 sets the PDSCH to which the transmission weight is set. You may make it not set the transmission weight of each adaptive array antenna 108A thru | or adaptive array antenna 108D corresponding to a frequency band.

  When the radio terminal UE2 has only one antenna and multi-stream communication MIMO (Multi Input Multi Output) is adopted for downlink radio communication, the AAS processing unit 136 performs the following processing. Do. That is, when precoding corresponding to MIMO is performed in the code or modulation unit 134, the AAS processing unit 136 sets the reception weight as the transmission weight (first transmission weight) for one layer and the other layer for the other layer. The second transmission weight orthogonal to the first transmission weight is used, and the first transmission weight, the second transmission weight, and the signal are combined by space division multiple access (SDMA). For example, when there are K antenna elements and two layers in the radio base station eNB1, if the first transmission weight of the Kth antenna element (element (k)) calculated based on the reception weight is WTX1 (k) The second transmission weight WTX2 (k) is obtained by the following equation 1. However, a plurality of second transmission weights can be obtained depending on the number of antenna elements in the radio base station eNB1. The combination of the layer 1 signal X1 and the first transmission weight WTX1 (k) of the element (k) and the combination of the layer 2 signal X2 and the second transmission weight WTX2 (k) of the element (k) 2 to obtain a combined weight W (k).

・・・（式１）

... (Formula 1)

・・・（式２）

... (Formula 2)

  The AAS processing unit 136 weights the frequency domain signal with the set transmission weight. Further, the AAS processing unit 136 outputs the weighted frequency domain signal to the IFFT processing unit 138.

  The IFFT processing unit 138 performs inverse fast Fourier transform on the weighted frequency domain signal to obtain a baseband signal. CP adding section 140 adds a CP to the input baseband signal. CP adding section 140 outputs the baseband signal with the CP added thereto to RF transmission processing section 107.

  The RF transmission processing unit 107 includes a mixer and a power amplifier (not shown). The RF transmission processing unit 107 converts (up-converts) the baseband signal to which the CP is added into a downlink radio signal in the radio frequency band. Further, the RF transmission processing unit 107 amplifies the downlink radio signal in the radio frequency band, and transmits the amplified downlink radio signal in the radio frequency band via the adaptive array antenna 108A to the adaptive array antenna 108D in which the transmission weight is set. Send.

  Thereafter, the RB allocating unit 120 in the control unit 102 stores the time indicated by the time stamp information among the reception weights stored in the memory 121 and corresponding to each adaptive array antenna 108A to adaptive array antenna 108D. Information on the frequency band corresponding to the reception weight within the period is read. The read frequency band information indicates the PUSCH frequency band for which the reception weight is calculated.

  The RB allocation unit 120 reallocates the downlink resource block based on the read frequency band information.

  Specifically, for the downlink resource block, the RB allocation unit 120 assigns a lower priority to the downlink resource block in the frequency band closer to the PUSCH frequency band in which the reception weight is calculated, which is indicated by the read frequency band information. Set priorities to be higher. The RB allocation unit 120 selects a downlink resource block according to the set priority order. Furthermore, when the selected downlink resource block is unused, the RB allocation unit 120 determines to allocate the downlink resource block.

  On the other hand, when the selected downlink resource block has been used, the RB allocation unit 120 selects the downlink resource block having the next priority after the downlink resource block. Thereafter, similarly to the above, the processing after the determination as to whether or not the selected downlink resource block is unused is repeated.

  The RB allocation unit 120 outputs a new RB allocation value corresponding to the downlink resource block whose allocation has been determined to the AAS processing unit 136. Also, the new RB allocation value is sent as control information to the radio terminal UE2.

  When a new RB allocation value is input, the AAS processing unit 136 performs the same process as described above. That is, the AAS processing unit 136 specifies the time zone and the frequency band of the downlink resource block newly allocated to the radio terminal UE2 based on the RB allocation value. The PDSCH in the identified downlink resource block is a PDSCH for which a transmission weight is set.

  Next, the AAS processing unit 136 has the time indicated by the time stamp information within the past predetermined period among the reception weights stored in the memory 121 and corresponding to each adaptive array antenna 108A to adaptive array antenna 108D. Receive weight is extracted.

  The AAS processing unit 136 identifies the reception weight closest to the PDSCH frequency band in the downlink resource block to which the corresponding frequency band is newly assigned among the extracted reception weights. Further, the AAS processing unit 136 sets the reception weight for each identified adaptive array antenna 108A to adaptive array antenna 108D to each adaptive array antenna 108A to 108A corresponding to the PDSCH frequency band in the newly allocated downlink resource block. The transmission weight of the adaptive array antenna 108D is set. The AAS processing unit 136 performs weighting processing for combining the set transmission weight and the frequency domain signal. Further, the AAS processing unit 136 outputs the weighted frequency domain signal to the IFFT processing unit 138.

  Thereafter, the IFFT processing unit 138 performs an inverse fast Fourier transform on the weighted frequency domain signal to obtain a baseband signal. CP adding section 140 adds a CP to the input baseband signal. CP adding section 140 outputs the baseband signal with the CP added thereto to RF transmission processing section 107.

  The RF transmission processing unit 107 converts (up-converts) the baseband signal to which the CP is added into a downlink radio signal in the radio frequency band. Further, the RF transmission processing unit 107 amplifies the downlink radio signal in the radio frequency band, and transmits the amplified downlink radio signal in the radio frequency band via the adaptive array antenna 108A to the adaptive array antenna 108D in which the transmission weight is set. Send.

(1.3) Configuration of Radio Terminal FIG. 4 is a configuration diagram of the radio terminal UE2. As illustrated in FIG. 4, the radio terminal UE2 includes a control unit 202, a storage unit 203, a radio frequency (RF) reception processing unit 205, a baseband (BB) processing unit 206, an RF transmission processing unit 207, and an antenna 208.

  The control unit 202 is configured by a CPU, for example, and controls various functions provided in the radio terminal UE2. The storage unit 203 is configured by a memory, for example, and stores various types of information used for control and the like in the radio terminal UE2.

  The RF reception processing unit 205 receives a downlink radio signal in the radio frequency band from the radio base station eNB1 via the adaptive array antenna 208. The RF reception processing unit 205 includes a low noise amplifier (LNA) and a mixer (not shown). The RF reception processing unit 205 amplifies the received downlink radio signal in the radio frequency band, and converts (down-converts) it into a baseband signal. Further, the RF reception processing unit 205 outputs the baseband signal to the BB processing unit 206.

  The BB processing unit 206 includes an RB allocation unit 220, a CP removal unit 222, an FFT processing unit 224, a channel equalization unit 228, a demodulation decoding unit 232, an encoding modulation unit 234, a DFT processing unit 236, an IFFT processing unit 238, and a CP addition. Part 240.

  The resource block allocation value (RB allocation value) obtained by the MAC layer processing in the control unit 202 is input to the RB allocation unit 220. When the radio terminal UE2 connects to the radio base station eNB1, the control unit 202 can recognize the allocated resource block based on the resource block allocation information from the radio base station eNB1. As described above, the RB allocation value includes a downlink resource block allocated to the radio terminal UE2 and a resource block number that is identification information of the uplink resource block. The RB allocation unit 220 outputs the RB allocation value to the channel equalization unit 228 and the DFT processing unit 236.

  CP removing section 222 removes the CP from the input baseband signal. The FFT processing unit 224 performs fast Fourier transform on the baseband signal from which the CP is removed, and obtains a frequency domain signal.

  Channel equalization section 228 identifies the frequency band of the downlink resource block allocated to radio terminal UE2 based on the RB allocation value from RB allocation section 220. Further, the channel equalization unit 228 performs channel equalization processing on the frequency domain signal corresponding to the frequency band of the downlink resource block allocated to the radio terminal UE2 among the frequency domain signals from the FFT processing unit 224. I do. The demodulation and decoding unit 232 performs demodulation and decoding processing on the signal that has been subjected to channel equalization processing. Thereby, the data transmitted by the radio base station eNB1 is obtained. Data is output to the control unit 202.

  When the data from the control unit 202 is input, the code modulation unit 234 performs coding and modulation on the data to obtain a frequency domain signal. The DFT processing unit 236 specifies the frequency band of the uplink resource block allocated to the radio terminal UE2 based on the RB allocation value from the RB allocation unit 220. Further, the DFT processing unit 236 performs a discrete Fourier transform on the frequency domain signal. The IFFT processing unit 238 performs an inverse fast Fourier transform on the signal subjected to the discrete Fourier transform to obtain a baseband signal. CP adding section 240 adds a CP to the input baseband signal. CP adding section 240 outputs the baseband signal to which the CP has been added to RF transmission processing section 207.

  The RF transmission processing unit 207 includes a mixer and a power amplifier (not shown). The RF transmission processing unit 207 converts (up-converts) the baseband signal to which the CP is added into an uplink radio signal in the radio frequency band. Further, the RF transmission processing unit 207 amplifies the uplink radio signal in the radio frequency band, and transmits the amplified uplink radio signal in the radio frequency band via the adaptive array antenna 108A to the adaptive array antenna 108D.

(2) Operation of Radio Communication System FIG. 5 is a sequence diagram showing the operation of the radio communication system 10. In step S101, the radio terminal UE2 transmits an uplink radio signal in the radio frequency band. The radio base station eNB1 receives an uplink radio signal in the radio frequency band.

  In step S102, the radio base station eNB1 detects a demodulation reference signal included in the received uplink radio signal.

  In step S103, the radio base station eNB1 determines, based on the demodulation reference signal, each adaptive array antenna 108A to adaptive array antenna 108D corresponding to the PUSCH frequency band in the uplink resource block allocated to the radio terminal UE2. Receive weight is calculated. Further, the radio base station eNB1 stores the calculated reception weights of the adaptive array antennas 108A to 108D.

  In step S104, the radio base station eNB1 calculates the frequency band of the PDSCH for which the corresponding frequency band is calculated in the past predetermined period from among the stored reception weights of each adaptive array antenna 108A to adaptive array antenna 108D. The reception weight closest to the band is specified. Further, the radio base station eNB1 sets the specified reception weight as the transmission weight of each adaptive array antenna 108A to adaptive array antenna 108D.

  In step S105, the radio base station eNB1 transmits the downlink radio signal in the radio frequency band from each adaptive array antenna 108A to adaptive array antenna 108D in which the transmission weight is set. The radio terminal UE2 receives a downlink radio signal in the radio frequency band.

  In step S106, the radio base station eNB1 reads information on the frequency band corresponding to the stored reception weight.

  In step S107, for the downlink resource block, the radio base station eNB1 has a higher allocation priority in the downlink resource block in the frequency band closer to the PUSCH frequency band for which the reception weight is calculated, which is indicated by the read frequency band information. Set the priority order so that Furthermore, the RB allocation unit 120 selects a downlink resource block according to the set priority, and determines that the downlink resource block is allocated when the selected downlink resource block is unused.

  In step S108, the radio base station eNB1 transmits allocation information including an RB allocation value corresponding to the downlink resource block whose allocation has been determined, to the radio terminal UE2. The radio terminal UE2 receives the allocation information and recognizes a newly allocated downlink resource block.

  After that, in step S109, the radio base station eNB1 is calculated within a predetermined period in the past among the stored reception weights of each adaptive array antenna 108A to adaptive array antenna 108D, and a corresponding frequency band is newly allocated. The reception weight closest to the PDSCH frequency band in the downlink resource block is specified. Further, the radio base station eNB1 sets the specified reception weight as the transmission weight of each adaptive array antenna 108A to adaptive array antenna 108D.

  In step S110, the radio base station eNB1 transmits a downlink radio signal in a radio frequency band from each of the adaptive array antennas 108A to 108D for which transmission weights are set. The radio terminal UE2 receives a downlink radio signal in the radio frequency band.

(3) Operation / Effect As described above, according to the present embodiment, when the radio base station eNB1 receives an uplink radio signal in the radio frequency band from the radio terminal UE2, the radio base station eNB1 for demodulation included in the uplink radio signal The reception weights of the adaptive array antennas 108A to 108D are calculated and stored based on the reference signals. Further, the radio base station eNB1 reads out information on the frequency band corresponding to the stored reception weight, and the downlink resource block in the frequency band close to the frequency band of the PUSCH for which the reception weight is calculated, indicated by the information on the frequency band. The downlink resource block is selected according to the priority set so that the priority of allocation becomes higher, and when the selected downlink resource block is unused, the downlink resource block is allocated.

  FIG. 6 is a diagram illustrating an example of a correspondence between a reception weight corresponding to PUSCH and a transmission weight corresponding to PDSCH. FIG. 6 shows an example in which frequency hopping is applied when uplink resource blocks are allocated. Before frequency hopping, resource block (RB) 11 is assigned as the PUSCH frequency band, and after frequency hopping, resource block (RB) 5 is assigned as the PUSCH frequency band in the time slot of time slot 1. In the time slot 2, the resource block (RB) 17 is assigned as the PUSCH frequency band.

  In such a situation, consider a case where only the reception weight calculated within the past 1 [ms] period is determined to be a transmission weight candidate. In this case, the AAS processing unit 136 extracts the reception weight of the frequency band corresponding to time slot 1 of RB5 and the reception weight of the frequency band corresponding to time slot 2 of RB17. Further, consider a case where it is determined that a reception weight is used as a transmission weight corresponding to a frequency band near the frequency band corresponding to the reception weight.

  In this case, the RB allocation unit 120 allocates the time slot 1 of RB3 and the time slot 2 of RB5, which are frequency bands in the vicinity of RB5, to the radio terminal UE2 in the frequency band of PDSCH, and in the frequency band in the vicinity of RB17. A time slot 1 of an RB 15 and a time slot 2 of an RB 17 are allocated to the radio terminal UE2. Further, for the time slot 1 of RB3 and the time slot 2 of RB5, the AAS processing unit 136 sets the reception weight of the frequency band corresponding to the time slot 1 of RB5 to the transmission weight. Further, the AAS processing unit 136 sets the reception weight of the frequency band corresponding to the time slot 1 of the RB 17 to the transmission weight for the time slot 1 of the RB 15 and the time slot 2 of the RB 17.

  By such downlink resource block allocation and transmission weight setting, the frequency band used for the downlink radio signal can be made as close as possible to the frequency band for which the reception weight is calculated, and the frequency band for which the reception weight is calculated. And the propagation environment of the frequency band used for the downlink radio signal are approximated. For this reason, even if the calculated reception weight is set as a transmission weight for the frequency band used for the downlink radio signal, the occurrence of a failure in the downlink radio communication is suppressed, and an appropriate adaptive array becomes possible.

(4) Other Embodiments As described above, the present invention has been described according to the embodiment. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  In the embodiment described above, the radio base station eNB1 calculates the reception weight based on the demodulation reference signal. However, the radio base station eNB1 may set the reception weight based on another signal included in the uplink radio signal.

  In the above-described embodiments, the TDD-LTE radio communication system has been described. However, radio communication employing up / down asymmetric communication in which the frequency band of the uplink radio signal allocated to the radio terminal is different from the frequency band of the downlink radio signal. The present invention can be similarly applied to any system.

  Thus, it should be understood that the present invention includes various embodiments and the like not described herein. Therefore, the present invention is limited only by the invention specifying matters in the scope of claims reasonable from this disclosure.

  eNB1 ... radio base station, UE2 ... radio terminal, 3 ... cell, 10 ... radio communication system, 102 ... control unit, 103 ... storage unit, 104 ... I / F unit, 105 ... RF reception processing unit, 106 ... BB processing unit 107 ... RF transmission processing unit, 108A, 108B, 108C, 108D ... adaptive array antenna, 120 ... RB allocation unit, 121 ... memory, 122 ... CP removal unit, 124 ... FFT processing unit, 126 ... AAS processing unit, 128 ... Channel equalization unit, 130 ... IDFT processing unit, 132 ... demodulation decoding unit, 134 ... coding modulation unit, 136 ... AAS processing unit, 138 ... IFFT processing unit, 140 ... CP addition unit, 202 ... control unit, 203 ... memory , 205 ... RF reception processing unit, 206 ... BB processing unit, 207 ... RF transmission processing unit, 208 ... antenna, 220 ... RB allocation unit, 222 ... CP Removed by unit, 224 ... FFT unit, 228 ... channel equalizer, 232 ... demodulation decoding unit, 234 ... encoding and modulation unit, 236 ... DFT unit, 238 ... IFFT section, 240 ... CP adding section

Claims (6)

An adaptive array wireless base station that transmits and receives wireless signals to and from wireless terminals using a plurality of antennas,
A calculation unit that calculates an antenna weight for each frequency band based on each of the reference signals for each of the plurality of frequency bands in the uplink radio signal;
An assigning unit for assigning a frequency band used for a downlink radio signal;
A setting unit for setting an antenna weight for a frequency band used for a downlink radio signal;
With
The allocation unit increases the priority when allocating the frequency band closer to the frequency band for which the antenna weight is calculated by the calculation unit as the frequency band used for the downlink radio signal,
The setting unit includes an antenna corresponding to a frequency band that is closest to a frequency band used for the downlink radio signal allocated by the allocation unit, among the antenna weights calculated by the calculation unit. A weight is set for the frequency band used for the downlink radio signal allocated by the allocation unit,
When the frequency difference between the frequency band in which the antenna weight is calculated and the frequency band used for the downlink radio signal is equal to or greater than a predetermined value, the setting unit sets the frequency band used for the downlink radio signal. On the other hand, a radio base station that does not set the calculated antenna weight in the frequency band in which the antenna weight is calculated .   The radio base station according to claim 1, wherein the calculation unit calculates an antenna weight for each frequency band based on each of reference signals for a plurality of frequency bands belonging to a predetermined time band in the uplink radio signal. . The predetermined time zone consists of a first time slot and a second time slot,
The calculation unit calculates an antenna weight of a frequency band corresponding to the first reference signal based on a first reference signal belonging to a time slot of the first half time slot in the uplink radio signal; 3. The radio base station according to claim 2, wherein an antenna weight of a frequency band corresponding to the second reference signal is calculated based on a second reference signal corresponding to a time slot of the second half time slot in the second radio signal. .   The setting unit extracts an antenna weight based on each of a plurality of reference signals belonging to a predetermined frequency band in a past predetermined period, and based on the extracted antenna weight, an antenna weight corresponding to the predetermined frequency band The radio base station according to claim 1, wherein When the wireless terminal has one antenna and downlink wireless communication is multi-stream communication,
The setting unit sets a first antenna weight for the frequency band of the downlink radio signal corresponding to the first layer, and sets the first antenna weight for the frequency band of the downlink radio signal corresponding to the second layer, The radio base station according to claim 1, wherein a second antenna weight orthogonal to the first antenna weight is set. A communication control method in an adaptive array radio base station that transmits and receives radio signals with a radio terminal using a plurality of antennas,
Calculating an antenna weight for each frequency band based on each reference signal for each of a plurality of frequency bands in an uplink radio signal;
Assigning a frequency band to be used for downlink radio signals;
Setting antenna weights for frequency bands used for downlink radio signals;
With
In the assigning step, the frequency band closer to the frequency band for which the antenna weight is calculated has a higher priority when set as a frequency band used for the downlink radio signal,
In the setting step, the antenna weight corresponding to the frequency band closest to the frequency band used for the assigned downlink radio signal is assigned to the assigned antenna weight among the calculated antenna weights. Set for the frequency band used for the downlink radio signal received,
In the setting step, when a frequency difference between the frequency band in which the antenna weight is calculated and a frequency band used for the downlink radio signal is equal to or greater than a predetermined value, the frequency band used for the downlink radio signal On the other hand, the communication control method does not set the calculated antenna weight in the frequency band in which the antenna weight is calculated .

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