JP5244631B2 - Wireless device and wireless communication method - Google Patents

Description

The present invention relates to a radio apparatus ( radio base station ) and a radio communication method using multi-antenna technology.

  In recent years, in a wireless communication system, in order to efficiently use a finite frequency band, a multi-antenna technique in which at least one of a transmission side and a reception side of a radio signal uses a plurality of antennas is used. As one of the multi-antenna technologies, a plurality of signal sequences using the same frequency band are simultaneously transmitted via a plurality of transmission antennas, and the signal sequence is received via a plurality of reception antennas and separated into each signal sequence. Multiple input multiple output (MIMO) communication is known.

  In MIMO communication, there is a method (so-called closed-loop MIMO) in which a reception side estimates propagation path characteristics with a transmission side, and feedback information based on the estimated propagation path characteristics is fed back to the transmission side. The transmission side performs various types of transmission control, for example, weighting for each transmission antenna, based on feedback information from the reception side. According to closed-loop MIMO, transmission quality can be improved because the transmission side can perform transmission control adapted to changes in propagation path characteristics.

Special table 2008-536342 gazette

  In recent years, in order to use the frequency band more efficiently, a wireless communication system using the same communication channel (specifically, the same frequency) between adjacent cells has been realized.

  In downlink communication in such a wireless communication system, a wireless terminal that receives a wireless signal receives not only a desired signal from a connected wireless base station but also interference signals from other wireless base stations located in the vicinity. May be received.

  However, in the above-described closed loop MIMO, closed feedback control is performed between the transmission side and the reception side, and when the wireless terminal receives an interference signal, the communication quality cannot be sufficiently improved. was there.

Accordingly, an object of the present invention is to provide a radio apparatus and a radio communication method capable of sufficiently improving communication quality even when a radio terminal receives an interference signal in downlink communication.

In order to solve the above-described problems, the present invention has the following features. First, a first feature of the present invention is that a transmission unit (transmission unit 412) that transmits a radio signal via a plurality of transmission antennas to a first radio terminal (radio terminal UE5) having a plurality of reception antennas, transmitted from the first wireless terminal, based on a first indicator indicating a transmission antenna weights directional beam of the plurality of transmitting antennas is formed faces the direction of the first wireless terminal, for controlling the directional beam A radio device (radio base station BS2) having a control unit (transmission directivity control unit 422), which receives the radio signal as an interference signal during communication with another radio device (radio base station BS1). transmitted from the radio terminal (radio terminal UE1), wherein the acquisition unit null point of the directional beam to obtain a second indicator indicating a transmission antenna weights facing the second wireless terminal (information acquiring unit 42 ) Wherein the control unit, wherein the first indicator based on a second indicator, the directional beam is oriented in the first wireless terminal end, and wherein the null in the second wireless terminal end The gist is to select a transmission antenna weight to which a point is directed .

According to such a radio apparatus , since the directional beam is directed toward the first radio terminal, the communication quality in the first radio terminal can be kept good. Furthermore, by directing the null point in the direction of the second wireless terminal, the second wireless terminal can be prevented from receiving an interference signal, and the communication quality in the second wireless terminal can be sufficiently improved.

  Therefore, communication quality can be sufficiently improved even when the wireless terminal receives an interference signal in downlink communication.

A second feature of the present invention relates to the first feature of the present invention, wherein the acquisition unit acquires the second indicator from the other wireless device , or the wireless device and the other wireless device. The gist is to obtain the second indicator from a control device (control device 100A) that controls the above.

A third aspect of the present invention, for the first wireless terminal having a plurality of receiving antennas, and transmitting radio signals through a plurality of transmit antennas, transmitted from the first wireless terminal, transmitting the plurality A directional beam formed by an antenna that controls the directional beam based on a first indicator that indicates a transmission antenna weight that is directed toward the first wireless terminal . A second indicator is transmitted from a second wireless terminal that receives the wireless signal as an interference signal during communication with a wireless device, and a null point of the directional beam is directed to the second wireless terminal to obtain a second indicator indicating a transmission antenna weight comprising the step, in the step of controlling, based on said first indicator and said second indicator, the directional beam to the first wireless terminal end is Come, and, and summarized in that selecting a transmission antenna weights the null point is directed to the second radio terminal end.

ADVANTAGE OF THE INVENTION According to this invention, even if it is a case where a radio | wireless terminal receives an interference signal in downlink communication, the radio | wireless apparatus and radio | wireless communication method which can fully improve communication quality can be provided.

1 is an overall configuration diagram of a wireless communication system according to a first embodiment of the present invention. It is a figure for demonstrating the channel used in the radio | wireless communications system which concerns on 1st Embodiment of this invention. It is a figure for demonstrating schematic operation | movement of the radio | wireless communications system which concerns on 1st Embodiment of this invention. It is a functional block diagram which shows the structure of the radio | wireless terminal which concerns on 1st Embodiment of this invention. It is a functional block diagram which shows the structure of the wireless base station (1st wireless base station) which concerns on 1st Embodiment of this invention. It is a functional block diagram which shows the structure of the control apparatus which concerns on 1st Embodiment of this invention. It is a functional block diagram which shows the structure of the wireless base station (2nd wireless base station) which concerns on 1st Embodiment of this invention. It is a figure for demonstrating the detail of the transmission directivity control performed in 1st Embodiment of this invention. It is a figure for demonstrating the detail of the transmission directivity control performed in 1st Embodiment of this invention. It is an operation | movement sequence diagram which shows operation | movement of the radio | wireless communications system which concerns on 1st Embodiment of this invention. It is a whole block diagram of the radio | wireless communications system which concerns on 2nd Embodiment of this invention. It is a functional block diagram which shows the structure of the wireless base station (1st wireless base station) which concerns on 2nd Embodiment of this invention. It is an operation | movement sequence diagram which shows operation | movement of the radio | wireless communications system which concerns on 2nd Embodiment of this invention.

  Next, a first embodiment and a second embodiment of the present invention will be described with reference to the drawings. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

[First Embodiment]
In the first embodiment, (1) an outline of the radio communication system 10A, (2) a detailed configuration of the radio communication system 10A, (3) transmission directivity control in the radio base station BS2, (4) operation of the radio communication system, ( 5) The effect will be described.

(1) Overview of Radio Communication System 10A An overview of the radio communication system 10A will be described in the order of (1.1) schematic configuration of the radio communication system 10A and (1.2) schematic operation of the radio communication system 10A.

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

  As illustrated in FIG. 1, the radio communication system 10A includes a radio terminal UE1, a radio terminal UE2, a radio terminal UE3, a radio terminal UE4, a radio terminal UE5, a radio base station BS1 (first radio base station), and a radio base station BS2 ( A second radio base station) and a control device 100A.

  In FIG. 1, for convenience of explanation, only the radio base station BS1 and the radio base station BS2 are illustrated, but actually, other radio base stations are installed adjacent to the radio base station BS1 and the radio base station BS2. Has been.

  The wireless communication system 10A has a configuration based on the LTE (Long Term Evolution) standard that is standardized in 3GPP (3rd Generation Partnership Project). In the first embodiment, mainly downlink (hereinafter, downlink) communication will be described.

  The radio base station BS1 is a connection destination of the radio terminals UE1 to UE4 located in the cell C1, and performs downlink communication with the radio terminals UE1 to UE4. Among the radio terminals UE1 to UE4, the radio terminals UE1 to UE3 are located at the end of the cell C1.

  The radio base station BS2 is a connection destination of the radio terminal UE5 located in the cell C2 adjacent to the cell C1, and performs downlink communication with the radio terminal UE5.

  The control device 100A is provided on a backbone network that is a wired communication network, and is wired to the radio base station BS1 and the radio base station BS2. The control device 100A controls the radio base station BS1 and the radio base station BS2.

  The radio communication system 10A employs an orthogonal frequency division multiple access (OFDMA) system, which is one of multicarrier communication systems. In the OFDMA scheme, a plurality of subcarriers are used to form a communication channel called a subchannel (hereinafter referred to as a channel), and the channel is assigned from a radio base station to a radio terminal. The radio communication system 10A employs a frequency division duplex (FDD) system as a duplex system.

  In the example of FIG. 1, the radio base station BS1 assigns channel A shown in FIG. 2 to the radio terminal UE1, channel B to the radio terminal UE2, channel C to the radio terminal UE3, and channel D to the radio terminal UE4. Yes. Hereinafter, a radio signal transmitted by the radio base station BS1 using these channels is referred to as a first radio signal.

  The radio base station BS2 assigns the channel A shown in FIG. 2 to the radio terminal UE5, and assigns channels B, C, and D to other radio terminals not shown. Hereinafter, a radio signal transmitted by the radio base station BS2 using these channels is referred to as a second radio signal.

  The radio terminal UE1 receives the first radio signal using the channel A as a desired signal from the connection-destination radio base station BS1, and receives the second radio signal using the channel A as an interference signal from the radio base station BS2. ing. The second radio signal using channel A arrives at the radio terminal UE1 from the radio base station BS2 toward the D1 direction.

  The radio terminal UE5 receives the second radio signal using the channel A as a desired signal from the radio base station BS2. The second radio signal using channel A arrives at the radio terminal UE1 in the direction D5 from the radio base station BS2.

  Similarly, the radio terminal UE2 receives the first radio signal using the channel B as a desired signal from the radio base station BS1 to which the radio terminal UE2 is connected, and receives the second radio signal using the channel B from the radio base station BS2 as an interference signal. As received. The second radio signal using channel B arrives at the radio terminal UE2 from the radio base station BS2 in the direction D2.

  The radio terminal UE3 receives the first radio signal using the channel C as a desired signal from the connection-destination radio base station BS1, and receives the second radio signal using the channel C as an interference signal from the radio base station BS2. ing. The second radio signal using channel C arrives at the radio terminal UE3 from the radio base station BS2 in the direction D3.

  The radio base station BS1 and the radio base station BS2 perform downlink communication based on the above-described closed loop MIMO.

  Specifically, the radio base station BS1 transmits the first radio signal to the radio terminals UE1 to UE4 via a plurality of antennas (first transmission antennas) provided in the radio base station BS1. The radio terminals UE1 to UE4 receive the first radio signals via a plurality of antennas (reception antennas) provided in the radio terminals UE1 to UE4, respectively.

  The radio base station BS2 transmits the second radio signal to the radio terminal UE5 via a plurality of antennas (second transmission antennas) provided in the radio base station BS2. The radio terminal UE5 receives the second radio signal via a plurality of antennas (reception antennas) provided in the radio terminal UE5.

  In the first embodiment, MIMO (so-called 4 × 2 MIMO) in which there are four transmission antennas and two reception antennas in downlink communication will be described.

  Each of the radio terminals UE1 to UE4 analyzes the first radio signal received from the radio base station BS1, and periodically provides feedback information for adaptively controlling multi-antenna transmission in the radio base station BS1 to the radio base station BS1. Send. The radio terminal UE5 analyzes the second radio signal received from the radio base station BS2, and periodically transmits feedback information for adaptively controlling multi-antenna transmission in the radio base station BS2 to the radio base station BS2.

  In the LTE standard, feedback information includes “RI (Rank Indicator)”, “PMI (Precoding Matrix Indicator)”, and “CQI (Channel Quality Indicator)”. The RI is information for controlling the number of streams (referred to as layers in the LTE standard) that are signal sequences. PMI is information for controlling transmit antenna weight (referred to as a precoding matrix in the LTE standard). CQI is information for controlling transmission power and modulation scheme. The RI, PMI, and CQI are also used for resource scheduling in the radio base stations BS1 and BS2.

  Each of the radio terminals UE1 to UE4 determines the number of layers, and transmits RI corresponding to the determined number of layers as feedback information to the radio base station BS1. Each of the radio terminals UE1 to UE4 calculates a precoding matrix that maximizes reception quality (for example, SNR) according to the number of layers, and transmits the PMI according to the calculation result to the radio base station BS1 as feedback information. Further, each of the radio terminals UE1 to UE4 obtains a CQI corresponding to the reception quality, and transmits the CQI to the radio base station BS1 as feedback information. The radio base station BS1 controls the number of layers, precoding matrix, transmission power, modulation scheme, and the like according to the feedback information.

  Similarly, the radio terminal UE5 analyzes the radio signal received from the radio base station BS2, and periodically provides feedback information (RI, PMI, CQI) for adaptively controlling multi-antenna transmission in the radio base station BS2. Transmit to the radio base station BS2.

(1.2) Schematic Operation of Radio Communication System 10A Next, a schematic operation of the radio communication system 10A will be described with reference to FIG.

  When receiving the second radio signal from the radio base station BS2 as an interference signal, the radio terminal UE1 estimates the arrival direction D1 of the second radio signal to the radio terminal UE1, and transmits interference information based on the arrival direction D1 to the radio base station. Transmit to station BS1.

  Further, when the radio terminal UE2 receives the second radio signal from the radio base station BS2 as an interference signal, the radio terminal UE2 estimates the arrival direction D2 of the second radio signal to the radio terminal UE2, and obtains interference information based on the arrival direction D2. Transmit to the radio base station BS1.

  When receiving the second radio signal from the radio base station BS2 as an interference signal, the radio terminal UE3 estimates the arrival direction D3 of the second radio signal to the radio terminal UE3, and transmits the interference information based on the arrival direction D3 to the radio base station. Transmit to station BS1.

  For example, the radio terminals UE1 to UE3 transmit interference information to the radio base station BS1 together with the feedback information described above.

  The radio base station BS1 relays interference information received from the radio terminals UE1 to UE3 to the control device 100A. 100 A of control apparatuses are based on the received interference information, and the directional beam which the some transmission antenna provided in radio base station BS2 forms with respect to each direction (arrival direction D1-D3) of radio | wireless terminals UE1-UE3. Control information for directing the null point (insensitive point) of the wireless device in the direction of arrival is transmitted to the radio base station BS2.

  A communication form in which MIMO communication is performed while forming a directional beam is generally referred to as beam forming MIMO.

  Based on the control information received from the control device 100A and the feedback information fed back from the radio terminal UE5, the radio base station BS2 directs null points in the directions D1 to D3 of the radio terminals UE1 to UE3 and A second radio signal is transmitted by directing a directional beam in a direction D5 of the terminal UE5.

  The interference information is, for example, information indicating a coefficient or angle indicating the arrival direction of the interference signal. An existing direction-of-arrival estimation technique can be used for estimating the direction of arrival. However, in estimating the arrival direction, it is necessary to obtain an absolute direction, not a relative direction that changes according to the state of the wireless terminal. When the arrival direction estimation technique for obtaining a relative direction is used, an absolute direction can be obtained by using in combination with a GPS or a direction sensor provided in the wireless terminal.

  In order to reduce the information amount of the interference information, information indicating the coefficient or angle indicating the arrival direction may be converted into PMI, and the PMI may be used as the interference information. In this case, the radio terminal UE1 transmits, as interference information, the PMI corresponding to the precoding matrix that directs the null point in the direction D1 of the radio terminal UE1 to the radio base station BS1.

  Similarly, the radio terminal UE2 transmits, as interference information, the PMI corresponding to the precoding matrix that directs the null point in the direction D2 of the radio terminal UE2 to the radio base station BS1. The radio terminal UE3 transmits the PMI corresponding to the precoding matrix that directs the null point in the direction D3 of the radio terminal UE3 as interference information to the radio base station BS1.

  When information indicating a coefficient or angle indicating the direction of arrival is used as interference information, information indicating a coefficient or angle indicating the direction of arrival is used as control information, or the information is converted into PMI and used. can do. When PMI is used as interference information, the PMI can be used as it is as control information.

  By using PMI as the interference information and control information, the information amount of the interference information and control information can be reduced, and mounting in the radio communication system 10A can be facilitated.

(2) Detailed Configuration of Radio Communication System 10A Next, regarding the detailed configuration of the radio communication system 10A, (2.1) configuration of the radio terminal UE1, (2.2) configuration of the radio base station BS1, (2.3) The configuration of the control device 100A and (2.4) the configuration of the radio base station BS2 will be described in this order. In the following, the configuration related to the present invention will be mainly described.

(2.1) Configuration of Radio Terminal UE1 FIG. 4 is a functional block diagram showing the configuration of the radio terminal UE1. Since the other radio terminals (radio terminals UE2 to UE5) are configured in the same manner as the radio terminal UE1, here, the radio terminal UE1 will be described as a representative of each radio terminal.

  As illustrated in FIG. 4, the radio terminal UE1 includes antennas 201 and 202, a radio communication unit 210, a control unit 220, and a storage unit 230.

  The wireless communication unit 210 includes a reception unit 211 that receives wireless signals via the antennas 201 and 202 and a transmission unit 212 that transmits wireless signals via the antennas 201 and 202. The receiving unit 211 performs channel estimation based on a pilot signal that is a known signal included in the first radio signal received from the radio base station BS1, and generates feedback information using the channel estimation result. The transmission unit 212 transmits the generated feedback information to the radio base station BS1.

  The control unit 220 is configured by a CPU, for example, and controls various functions provided in the radio terminal UE1. The storage unit 230 is configured by a memory, for example, and stores various information used for control and the like in the radio terminal UE1.

  The control unit 220 includes an arrival direction estimation unit 221 and an interference information generation unit 222.

  The arrival direction estimation unit 221 estimates the arrival direction D1 of the second radio signal to the radio terminal UE1 when the reception unit 211 receives the second radio signal (interference signal) from the radio base station BS2.

  The interference information generation unit 222 generates interference information based on the arrival direction D1 estimated by the arrival direction estimation unit 221. When PMI is used as the interference information as described above, the storage unit 230 holds the association between the arrival direction D1 and the PMI in advance, and the interference information generation unit 222 generates the PMI from the association ( get. Then, the transmission unit 212 transmits interference information to the radio base station BS1.

(2.2) Configuration of Radio Base Station BS1 FIG. 5 is a functional block diagram showing the configuration of the radio base station BS1.

  As illustrated in FIG. 5, the radio base station BS1 includes antennas 301 to 304, a radio communication unit 310, a control unit 320, a storage unit 330, and a wired communication unit 340.

  The radio communication unit 310 receives a radio signal from the radio terminals UE1 to UE4 via the antennas 301 to 304, and a transmission unit 312 transmits the radio signal to the radio terminals UE1 to UE4 via the antennas 301 to 304. And have. The receiving unit 311 acquires feedback information included in the received radio signal. In addition, the reception unit 311 acquires interference information included in the received radio signal.

  The transmission unit 312 controls multi-antenna transmission based on the feedback information. Specifically, the transmission unit 312 distributes the transmission signal to a plurality of layers according to RI, weights the transmission signal of each layer according to PMI (hereinafter, precoding), and converts the transmission signal after precoding to CQI. Accordingly, adaptive modulation and transmission power control are performed.

  The control unit 320 is configured by a CPU, for example, and controls various functions provided in the radio base station BS1. The storage unit 330 is configured by a memory, for example, and stores various types of information used for control and the like in the radio base station BS1. The wired communication unit 340 is connected to the control device 100A via a wired communication network. The wired communication unit 340 transmits interference information to the control device 100A.

(2.3) Configuration of Control Device 100A FIG. 6 is a functional block diagram showing the configuration of the control device 100A.

  As illustrated in FIG. 6, the control device 100A includes a wired communication unit 110, a control unit 120, and a storage unit 130.

  The wired communication unit 110 is connected to the radio base stations BS1 and BS2 via a wired communication network. The wired communication unit 110 includes a reception unit 111 that receives a signal and a transmission unit 112 that transmits a signal. The receiving unit 111 receives interference information from the radio base station BS1.

  The control unit 120 is constituted by a CPU, for example, and controls various functions provided in the control device 100A. The storage unit 130 is configured by a memory, for example, and stores various information used for control and the like in the control device 100A.

  The control unit 120 includes an interference source specifying unit 121 and a control information generation unit 122. The interference source specifying unit 121 specifies a radio base station as an interference source from among a plurality of radio base stations. A method for specifying the interference source will be described later. The control information generation unit 122 generates control information based on the interference information received by the reception unit 111. The transmitter 112 transmits the control information to the radio base station BS2.

(2.4) Configuration of Radio Base Station BS2 FIG. 7 is a functional block diagram showing the configuration of the radio base station BS2.

  As illustrated in FIG. 7, the radio base station BS2 includes antennas 401 to 404, a radio communication unit 410, a control unit 420, a storage unit 430, and a wired communication unit 440.

  The radio communication unit 410 includes a reception unit 411 that receives radio signals from the radio terminal UE5 via the antennas 401 to 404, and a transmission unit 412 that transmits radio signals to the radio terminal UE5 via the antennas 401 to 404.

  The receiving unit 411 acquires feedback information included in the radio signal received from the radio terminal UE5. The transmission unit 412 controls multi-antenna transmission based on the feedback information. Specifically, the transmission unit 412 distributes the transmission signal to a plurality of layers according to RI, precodes the transmission signal of each layer according to PMI, and applies adaptive modulation and CQI to the transmission signal after precoding. Perform transmission power control.

  The control unit 420 is configured by a CPU, for example, and controls various functions provided in the radio base station BS2. The storage unit 430 is configured by a memory, for example, and stores various types of information used for control in the radio base station BS2. The wired communication unit 440 is connected to the control device 100A via a wired communication network. The wired communication unit 440 receives control information from the control device 100A.

  The control unit 420 includes an information acquisition unit 421 and a transmission directivity control unit 422. The information acquisition unit 421 acquires control information for directing the null point toward the radio terminals UE1 to UE3 that receive the second radio signal as an interference signal during communication with another radio base station (radio base station BS1). Configure the acquisition unit.

  The transmission directivity control unit 422 constitutes a control unit that controls the directional beams formed by the antennas 401 to 404 based on feedback information fed back from the radio terminal UE5. Specifically, the directional beam formed by the antennas 401 to 404 can be directed toward the radio terminal UE5 by precoding using a precoding matrix corresponding to the PMI fed back from the radio terminal UE5. Further, the transmission directivity control unit 422 directs the directional beam in the direction D5 of the radio terminal UE5 based on the feedback information and the control information acquired by the information acquisition unit 421, and the directions of the radio terminals UE1 to UE3. A null point is directed to D1 to D3.

(3) Transmission Directivity Control in Radio Base Station BS2 Next, details of transmission directivity control executed by the transmission directivity control unit 422 will be described using FIG. 8 and FIG. Here, a case where the null point is directed in the direction of the radio terminal UE1 (D1 direction) will be described as an example.

  Based on the control information, the transmission directivity control unit 422 selects a precoding matrix group that directs a null point in the direction of the radio terminal UE1 (D1 direction). As shown in FIG. 8, the precoding matrix group is a group including a plurality of precoding matrices having null points in the same direction, and is stored in advance in the storage unit 430. In the example of FIG. 8, precoding matrix groups 1 to 8 having null points in different directions are illustrated.

  As shown in FIG. 9, the precoding matrix group includes a plurality of precoding matrices each having a directional beam in a different direction. In the example of FIG. 9, each of the precoding matrices 1 to 6 included in the precoding matrix group 1 has directional beams in six directions. The directional beam patterns of the precoding matrices 1 to 6 are different.

  Based on feedback information (specifically, PMI) fed back from the radio terminal UE5 from the precoding matrix group having a null point in the direction D1 of the radio terminal UE1, the transmission directivity control unit 422 A precoding matrix having a directional beam in direction D5 of UE5 is selected. The selected precoding matrix is applied to precoding in the transmission unit 412.

(4) Operation of Radio Communication System FIG. 10 is an operation sequence diagram showing the operation of the radio communication system 10A. In FIG. 10, only PMI is illustrated and described among feedback information (RI, PMI, CQI) according to the LTE standard. Note that the operation sequence shown in FIG. 10 is repeatedly executed at predetermined time intervals (for example, in communication frame units).

  In steps S101, S103, and S105, the transmission unit 312 of the radio base station BS1 transmits the first radio signal using the channel A to the radio terminal UE1, the first radio signal using the channel B to the radio terminal UE2, and the channel C. The first radio signal using is transmitted to each radio terminal UE3.

  In steps S102, S104, and S106, the transmission unit 412 of the radio base station BS2 transmits the second radio signal using the channel A to the radio terminal UE5 and the second radio signal using the channel B to the radio terminal UE6 (not shown). The second radio signal using channel C is transmitted to radio terminal UE7 (not shown). At that time, the radio terminals UE1, UE2 and UE3 located in the self-ringe of the radio base station BS1 receive the first radio signal transmitted by the radio base station BS1 as a desired signal and the second radio signal transmitted by the radio base station BS2 A radio signal is received as an interference signal.

  In Steps S107a, S107b, and S107c, the receiving units 211 of the radio terminals UE1, UE2, and UE3 execute the channel response of the radio propagation path based on the pilot signal included in the first radio signal received from the radio base station BS1. Perform channel estimation. Each of the reception units 211 of the radio terminals UE1, UE2, and UE3 is based on a pilot signal included in the second radio signal received from the radio base station BS2 or a cell ID included in the second radio signal. Base station identification information for identifying BS2 is acquired.

  In Steps S108a, S108b, and S108c, the receiving units 211 of the radio terminals UE1, UE2, and UE3 calculate a precoding matrix based on the estimated channel response, and obtain a PMI corresponding to the calculated precoding matrix. .

  In step S109a, the arrival direction estimation unit 221 of the radio terminal UE1 estimates the arrival direction D1 of the second radio signal to the radio terminal UE1. The interference information generation unit 222 of the radio terminal UE1 generates interference information based on the arrival direction D1.

  In step S109b, the arrival direction estimation unit 221 of the radio terminal UE2 estimates the arrival direction D2 of the second radio signal to the radio terminal UE2. The interference information generation unit 222 of the radio terminal UE2 generates interference information based on the arrival direction D2.

  In step S109c, the arrival direction estimation unit 221 of the radio terminal UE3 estimates the arrival direction D3 of the second radio signal to the radio terminal UE3. The interference information generation unit 222 of the radio terminal UE3 generates interference information based on the arrival direction D3.

  In steps S110a, S110b, and S110c, the receiving units 211 of the radio terminals UE1, UE2, and UE3 equalize the received signal (channel equalization) based on the estimated channel response, and decode the equalized received signal To do. The decoded received signal is input to the control unit 220 of each of the radio terminals UE1, UE2, and UE3.

  In steps S111a, S111b, and S111c, the transmission units 212 of the radio terminals UE1, UE2, and UE3 transmit interference information, PMI, and base station identification information to the radio base station BS1. The receiving unit 311 of the radio base station BS1 receives interference information, PMI, and base station identification information.

  In step S112, the transmission unit 312 of the radio base station BS1 selects a precoding matrix corresponding to the PMI received from the radio terminal UE1. The transmitter 312 performs precoding using a precoding matrix corresponding to the PMI received from the radio terminal UE1 when the first radio signal using the channel A is next transmitted to the radio terminal UE1.

  Similarly, the transmitter 312 of the radio base station BS1 uses the precoding matrix corresponding to the PMI received from the radio terminal UE2 when the first radio signal using the channel B is next transmitted to the radio terminal UE2. Do coding. The transmitter 312 performs precoding using a precoding matrix corresponding to the PMI received from the radio terminal UE3 when the first radio signal using the channel C is next transmitted to the radio terminal UE3.

  In step S113, the wired communication unit 340 of the radio base station BS1 transmits the interference information and the base station identification information received from the radio terminals UE1, UE2, and UE3 to the control device 100A. The receiving unit 111 of the control device 100A receives interference information and base station identification information.

  In step S114, the interference source specifying unit 121 of the control device 100A specifies the radio base station BS2 as an interference source from the plurality of radio base stations based on the base station identification information received by the receiving unit 111. The control information generation unit 122 of the control device 100A generates control information addressed to the radio base station BS2 identified by the interference source identification unit 121 based on the interference information received by the reception unit 111. Specifically, the control information generation unit 122 corresponds to control information corresponding to channel A (wireless terminal UE1), control information corresponding to channel B (wireless terminal UE2), and channel C (wireless terminal UE3). Control information.

  In step S113, the transmission unit 112 of the control device 100A transmits the control information generated by the control information generation unit 122 to the radio base station BS2. The wired communication unit 440 of the radio base station BS2 receives control information.

  On the other hand, the receiving unit 411 of the radio base station BS2 receives PMI as feedback information from the radio terminal UE5, the radio terminal UE6 (not shown), and the radio terminal UE7 (not shown) that are connected to the radio base station BS2. Receiving. The information acquisition unit 421 of the radio base station BS2 acquires control information from the wired communication unit 440 and acquires PMI from the reception unit 411.

  In step S116, the transmission directivity control unit 422 of the radio base station BS2 directs a directional beam in the direction D5 of the radio terminal UE5 when the transmission unit 412 transmits the second radio signal using the channel A, and The transmitter 412 is controlled so that the null point is directed to D1 of the radio terminal UE1. Specifically, the transmission directivity control unit 422 selects a precoding matrix that directs the directional beam in the direction D5 of the radio terminal UE5 from among the precoding matrix groups that direct the null point in the direction D1 direction of the radio terminal UE1. To do.

  Similarly, the transmission directivity control unit 422 directs a directional beam in the direction of the radio terminal UE6 (not shown) when the transmission unit 412 transmits the second radio signal using the channel B, and the radio terminal The transmitter 412 is controlled so that the null point is directed in the direction of UE2 (D2 direction).

  Also, the transmission directivity control unit 422 directs a directional beam in the direction of the radio terminal UE7 (not shown) when the transmission unit 412 transmits the second radio signal using the channel C, and the radio terminal UE3. The transmission unit 412 is controlled so that the null point is directed in the direction (D3 direction).

(5) Effect According to the radio communication system 10A according to the first embodiment, when the radio terminals UE1 to UE3 receive the second radio signal from the radio base station BS2 as an interference signal, the radio terminal in the radio base station BS2 A null point is directed to directions D1 to D3 of UE1 to UE3. For this reason, it can avoid that radio | wireless terminal UE1 receives a 2nd radio signal (interference signal), and the communication quality in radio | wireless terminal UE1 can fully be improved. Thus, by preventing the generation of interference signals from the beginning, cell throughput is increased and high-speed downlink communication can be provided to each wireless terminal.

  In the first embodiment, the transmission directivity control unit 422 of the radio base station BS2 determines the directions of the radio terminals UE1 to UE3 based on the control information received from the control device 100A and the feedback information fed back from the radio terminal UE5. The second radio signal is transmitted with the null point directed to D1 to D3 and the directional beam directed to the direction D5 of the radio terminal UE5. Therefore, the communication quality in the radio terminal UE5 can be kept good while sufficiently improving the communication quality in the radio terminal UE1.

  In the first embodiment, the interference source identifying unit 121 of the control device 100A identifies the radio base station BS2 from the plurality of radio base stations based on the base station identification information, and controls the identified radio base station BS2 with control information. Send. Accordingly, even when there are a plurality of radio base stations that are candidates for interference sources, the interference sources can be easily identified, and control information can be transmitted to an appropriate radio base station.

[First Modification of First Embodiment]
In the first embodiment described above, the interference source specifying unit 121 of the control device 100A specifies the interference source radio base station BS2 from the plurality of radio base stations based on the base station identification information. The interference source may be specified by the method as described above.

  In the present modification example, the storage unit 130 of the control device 100A holds correspondence information in which interference information is associated with each radio base station in advance. Based on the interference information received by the receiving unit 111 and the base station identification information held by the receiving unit 111, the interference source identifying unit 121 of the control device 100A selects the radio base station BS2 that is the interference source from the plurality of radio base stations. Identify.

  According to such a method, since it is not necessary to transmit / receive base station identification information, the amount of information transmitted / received can be reduced as compared with the first embodiment.

[Modification 2 of the first embodiment]
In the first embodiment described above, information indicating a coefficient or angle indicating an arrival direction, or PMI is used as interference information and control information.

  However, position information indicating the positions of the radio terminals UE1, UE2, and UE3 may be used as interference information and control information. In this case, an existing position detection method such as position detection using GPS can be used. When position information is used as interference information and control information, the transmission directivity control unit 422 of the radio base station BS2 specifies the directions of the radio terminals UE1, UE2, and UE3 from the positions of the radio terminals UE1, UE2, and UE3. do it.

[Modification 3 of the first embodiment]
In the first embodiment described above, the information acquisition unit 421 of the radio base station BS2 has acquired the information indicating the coefficient or angle indicating the arrival direction or the PMI as the control information. May be obtained.

  Specifically, when the radio base station BS2 receives uplink radio signals from the radio terminals UE1, UE2, and UE3, the information acquisition unit 421 estimates the arrival direction of the uplink radio signal and indicates the estimated arrival direction Information may be acquired as control information. In this case, the transmission directivity control unit 422 of the radio base station BS2 may specify the directions of the radio terminals UE1, UE2, and UE3 from the arrival direction of the uplink radio signal.

[Second Embodiment]
In the first embodiment described above, the control device 100A is provided separately for the radio base station BS1 and the radio base station BS2. In the second embodiment, a mode in which the control device 100A is included in the radio base station BS1 will be described.

  In the second embodiment, (1) the configuration of the radio communication system 10B, (2) the operation of the radio communication system, and (3) the effects will be described.

(1) Configuration of Radio Communication System 10B FIG. 11 is an overall configuration diagram of a radio communication system 10B according to the second embodiment.

  As shown in FIG. 11, in the radio communication system 10B, the radio base station BS2 'has the function of the control device 100B. Specifically, as illustrated in FIG. 12, the control unit 320 of the radio base station BS2 'includes an interference source specifying unit 321 that specifies an interference source, and a control information generating unit 322 that generates control information. The functions of the interference source specifying unit 321 and the control information generating unit 322 are the same as the functions of the interference source specifying unit 121 and the control information generating unit 122 described in the first embodiment.

(2) Operation of Radio Communication System FIG. 13 is an operation sequence diagram showing the operation of the radio communication system 10B. In FIG. 13, the processes up to step S213 are the same as those in the first embodiment, and therefore, the processes after step S213 will be described.

  In step S213, the interference source specifying unit 321 of the radio base station BS1 'specifies the radio base station BS2 as an interference source from among the plurality of radio base stations based on the base station identification information received by the receiving unit 311. The control information generating unit 322 of the radio base station BS1 'generates control information addressed to the radio base station BS2 specified by the interference source specifying unit 321 based on the interference information received by the receiving unit 311.

  Specifically, the control information generation unit 322 corresponds to control information corresponding to channel A (wireless terminal UE1), control information corresponding to channel B (wireless terminal UE2), and channel C (wireless terminal UE3). Control information.

  In step S214, the wired communication unit 340 of the radio base station BS1 'transmits the control information generated by the control information generation unit 322 to the radio base station BS2. The wired communication unit 440 of the radio base station BS2 receives control information.

  In step S215, the transmission directivity control unit 422 of the radio base station BS2 directs a directional beam in the direction D5 of the radio terminal UE5 when the transmission unit 412 transmits the second radio signal using the channel A, and The transmitter 412 is controlled so that the null point is directed in the direction D1 of the radio terminal UE1.

  Similarly, the transmission directivity control unit 422 directs a directional beam in the direction of the radio terminal UE6 (not shown) when the transmission unit 412 transmits the second radio signal using the channel B, and the radio terminal The transmitter 412 is controlled so that the null point is directed in the direction D2 of the UE2.

  Also, the transmission directivity control unit 422 directs a directional beam in the direction of the radio terminal UE7 (not shown) when the transmission unit 412 transmits the second radio signal using the channel C, and the radio terminal UE3. The transmission unit 412 is controlled so that the null point is directed in the direction D3.

(3) Effects According to the wireless communication system 10B according to the second embodiment, the following effects can be obtained in addition to the effects of the first embodiment. That is, since it is not necessary to separately provide the control device 100B, the installation cost of the control device 100B can be reduced.

[Other Embodiments]
As mentioned above, although this invention was described by embodiment, it should not be understood that the description and drawing which form a part of this indication limit this invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, each of Modification Examples 1 to 3 of the first embodiment is applicable not only to the first embodiment but also to the second embodiment.

  In the first and second embodiments described above, when each of the radio terminals UE1 to UE3 receives the second radio signal from the radio base station BS2, the second radio signal is regarded as an interference signal. A second radio signal less than the reception level may be allowed. In this case, each of the radio terminals UE1 to UE3 receives the second radio signal from the radio base station BS2, and when the reception level of the second radio signal is equal to or higher than a predetermined reception level, the second radio signal Are regarded as interference signals.

  In the first and second embodiments, the FDD scheme is adopted as the duplex scheme, but a time division duplex (TDD) scheme may be adopted instead of the FDD scheme.

  The first and second embodiments have described the case where there are four transmission antennas and two reception antennas (4 × 2 MIMO) in downlink communication. However, in downlink communication, when there is one receiving antenna, that is, a multi-antenna transmission with multiple inputs and outputs (MISO) may be implemented.

  In the first and second embodiments, each of the radio base stations BS1 and BS2 performs radio communication with a plurality of radio terminals. However, each of the radio base stations BS1 and BS2 performs radio communication with one radio terminal. But you can.

  In the first and second embodiments, the wireless communication systems 10A and 10B based on the LTE standard have been described. The present invention can be applied to the UMB (Ultra Mobile Broadband) standard.

  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.

  DESCRIPTION OF SYMBOLS 10A, 10B ... Wireless communication system, 100A, 100B ... Control apparatus, 110 ... Wired communication part, 111 ... Reception part, 112 ... Transmission part, 120 ... Control part, 121 ... Interference source specific part, 122 ... Control information generation part, DESCRIPTION OF SYMBOLS 130 ... Memory | storage part, 201,202 ... Antenna, 210 ... Radio | wireless communication part, 211 ... Reception part, 212 ... Transmission part, 220 ... Control part, 221 ... Arrival direction estimation part, 222 ... Interference information generation part, 230 ... Memory | storage part , 301 to 304 ... antenna, 310 ... wireless communication unit, 311 ... reception unit, 312 ... transmission unit, 320 ... control unit, 321 ... interference source specifying unit, 322 ... control information generation unit, 330 ... storage unit, 340 ... wired Communication unit 401-404 ... Antenna 410 ... Wireless communication unit 411 ... Reception unit 412 ... Transmission unit 420 ... Control unit 421 ... Information acquisition unit 422 ... Transmission directivity control unit 430 ... storage unit, 440 ... wire communication unit

Claims (3)

A first wireless terminal having a plurality of receiving antennas, a transmitting unit for transmitting wireless signals via the plurality of transmitting antennas;
Transmitted from the first wireless terminal, based on a first indicator indicating a transmission antenna weights directional beam of the plurality of transmitting antennas is formed faces the direction of the first wireless terminal, for controlling the directional beam A wireless device having a control unit,
A second indicator indicating a transmission antenna weight transmitted from a second radio terminal that receives the radio signal as an interference signal during communication with another radio apparatus, and a null point of the directional beam is directed to the second radio terminal ; It has an acquisition unit to acquire,
Transmitting the control unit, based on the first indicator and said second indicator, the directional beam is oriented in the first wireless terminal end, and, where the null point is directed to the second wireless terminal end A wireless device that selects antenna weights . The acquisition unit acquires the second indicator from the other wireless device, or, in claim 1 to obtain the second indicator from the control device for controlling said wireless device and the other wireless device The wireless device described. Transmitting a wireless signal to a first wireless terminal having a plurality of receiving antennas via a plurality of transmitting antennas;
Transmitted from the first wireless terminal, based on a first indicator indicating a transmission antenna weights directional beam of the plurality of transmitting antennas is formed faces the direction of the first wireless terminal, for controlling the directional beam A wireless communication method comprising the steps of:
A second indicator indicating a transmission antenna weight transmitted from a second radio terminal that receives the radio signal as an interference signal during communication with another radio apparatus, and a null point of the directional beam is directed to the second radio terminal ; With a step to get
In the step of controlling, based on said first indicator and said second indicator, the directional beam is oriented in the first wireless terminal end, and the null point is directed to the second wireless terminal end A wireless communication method for selecting a transmission antenna weight .

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