JP2008236222A - Radio communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform communication with a rate corresponding to varied receiving quality in each slot caused by the presence or absence of the occurrence of adjacent cell interference, in a variable-rate communication system in which a beam is switched in time division by an array antenna. <P>SOLUTION: A mobile station measures the pilot signals of the self-cell and an adjacent cell, estimates the receiving quality in case of no adjacent cell interference, and requests a downlink communication rate to a base station (processing 104). Based on beam direction schedule information shared with an adjacent base station, the base station confirms, on a slot-by-slot basis, whether the adjacent cell interference occurs (processing 109). When scheduling a mobile station having no occurrence of interference, the mobile station transmits a data with a communication rate determined on the basis of the receiving quality (processing 110). Meanwhile, when the interference occurs, the mobile station converts the data into a short packet format having a reduced transmission data amount (processing 109), so as to transmit with a transmission speed reducing an error rate (processing 110). By this, communication suitable for an interference state is performed. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless communication method, and more particularly to a communication method for performing cellular communication, and in an array antenna type wireless apparatus having a plurality of antennas in a base station, forms a beam in time division and performs packet transmission. The present invention relates to a wireless communication method.

  An antenna used in a cellular system base station is a directional antenna for constituting a sector, and there is a case where an array antenna for further subdividing the sector is not added. Each base station uses the same frequency channel, and communication with each other may cause interference. The base station transmits pilot signals, and the wireless terminal receives these signals and measures the respective signal levels. The wireless terminal can calculate C / I (carrier power to interference power ratio) from the measured signal level. The downlink transmission data rate is calculated from the calculated C / I. The calculated transmission data rate is transmitted to the nearest base station via radio. The base station modulates user information sent from the network by designating a data rate selected by the wireless terminal among a plurality of modulators prepared based on this information. The modulated signal is transmitted as a radio signal from the antenna of the base station using a radiation pattern similar to that of the pilot signal.

  As an example of a cellular system, a cdma2000 1xEV-DO system is taken up. Detailed specifications of this system can be obtained from Non-Patent Document 1, for example. In this system, the pilot channel and data channel transmitted from the base station are multiplexed by time division. The wireless terminal sequentially calculates the downlink transmission data rate from the C / I of the time-division multiplexed pilot signal, and sequentially requests the data rate value from the base station. The base station modulates and transmits data according to the data rate requested by the wireless terminal. If the transmission data length is short from the A standard (for example, Non-Patent Document 1: Page 720, 10.7 Enhanced Forward Traffic Channel MAC Protocol), the transmission rate is converted to a short packet format with a reduced transmission data amount. By dropping and modulating, the packet can be transmitted with a reduced error rate. This standard is standardized assuming transmission of a packet with a small amount of data such as a VoIP packet. The specification of the radiation pattern formation by the antenna and the downlink data rate determination method in the system using the antenna is not specified in Non-Patent Document 1 and other documents.

  An example of a method for determining a downlink data rate in a base station system using an array antenna in a cdma2000 1xEV-DO system is disclosed in Patent Document 1. In the disclosed method, an array antenna is used to divide a sector with a narrow beam pattern, and interference power is measured from pilot signals transmitted by the plurality of beam patterns to estimate C / I, and a downlink data rate is set. Ask. The application of Patent Document 2 is a divisional application of Patent Document 1 and discloses a similar technique.

  Patent Document 3 discloses an example of a method for avoiding interference by sharing SIR (Signal to Interference Ratio) information between base stations in fixed radio. In the disclosed method, interference is estimated at the reception side of each communication device (base station and terminal) at the start of communication or by periodic operation. Alternatively, the signal to total interference signal ratio is estimated. A database having data indicating the mutual interference is installed, and each communication device stores interference information in the database. Interference in the corresponding time slot is determined by accessing the database from the base station, and communication is performed by selecting a slot with sufficiently low interference. If strong interference is estimated in all slots, no slot is assigned.

  Another method is disclosed in Patent Document 4. In the disclosed system, a plurality of base stations transmit pilot signals that are narrow beam patterned using an array antenna. The wireless terminal receives pilot signals transmitted from each of the plurality of base stations, estimates their propagation path, and transmits them to the base station as propagation path information. The base station estimates downlink signal quality using the propagation path information received from the wireless terminal and scheduling information shared with neighboring base stations, and determines the downlink transmission rate to the wireless terminal. Then, using the downlink transmission rate, a data packet is transmitted with a narrow beam pattern directed toward the wireless terminal.

The Third Generation Partnership Project 2 (3GPP2) Specifications, [online], C.I. S0024-Av2.0 cdma2000 High RatePacket DataAir Interface Specification, [Search September 19, 2006], Internet <URL: http: // www. 3gpp2. org / Public_html / specs / tsgc. cfm>, page 720 JP 2003-338803 A JP 2005-143148 A JP-A-10-155181 JP 2003-304777 A

  In cdma2000 1xEV-DO, the pilot signal and the user data signal are transmitted using the same fixed antenna pattern (for example, an omni pattern or a sector pattern). Therefore, the radio terminal side estimates the propagation path at the time of user data transmission from the pilot signal, selects one appropriate downlink data rate for the estimated propagation path, and requests the value from the base station side. We were able to communicate at an appropriate downlink data rate. However, in a base station having an array antenna, a user data signal is transmitted by an individual antenna pattern (for example, a beam pattern) directed toward the wireless terminal, so that it is viewed by a wireless terminal located at a cell boundary. Depending on the presence / absence of a beam pattern from an adjacent cell for each slot, interference may or may not occur. Therefore, although the signal quality of user data varies greatly depending on the presence / absence of interference, the downlink data rate requested from the wireless terminal is one value estimated from a common pilot signal, and is a value that does not depend on the presence / absence of interference. Therefore, when interference from an adjacent cell occurs, there is a possibility that the signal of that slot cannot be received.

  For example, the base station always (for example, periodically) transmits a pilot signal as an omni pattern to a wireless terminal to estimate a propagation path. On the other hand, the base station transmits user data signals in the direction of the wireless terminal by the array antenna, for example, by switching each slot with directivity such as a sector pattern or a beam pattern. For this reason, the amount of interference from adjacent cells may differ between when a pilot signal is transmitted and when a user data signal is transmitted. In the case of a slot in which interference occurs due to a sector pattern or a beam pattern, it is difficult to accurately predict the reception quality when receiving a data signal based on the reception quality of a pilot signal transmitted using an omni pattern. Therefore, packet loss may occur in a slot where interference occurs, and thus throughput may be reduced.

  In the method of the first embodiment disclosed in Patent Literature 1, space-time packet scheduling is performed so that adjacent base stations cooperate with each other and the interference between adjacent cells is reduced in the wireless terminal. Based on this assumption, the wireless terminal estimates C / I based on the largest pilot signal level of the connecting base station and the smallest pilot signal level of the interfering base station, that is, when there is the least interference from adjacent cells. Then, the method of selecting the downlink data rate based on the value is adopted. However, in this method, for example, the following problem occurs depending on the distribution of wireless terminals.

  First, for example, when all of the plurality of second wireless terminals under the second base station of the adjacent cell are distributed in the direction of the first wireless terminal connected to the desired first base station, the second of the adjacent cell The user data signal radiated from the base station has a beam pattern directed toward the first wireless terminal in all slots. Therefore, the desired first base station does not allocate a slot because the first wireless terminal always determines that the interference is large. Therefore, the first wireless terminal cannot communicate at all and the throughput may decrease.

  Secondly, a case is considered in which all of the plurality of first wireless terminals under the desired first base station are distributed in the direction of one second wireless terminal under the second base station of the adjacent cell. In the slot in which the second base station of the adjacent cell sends user data with directivity to the second wireless terminal, it is determined that the interference is large for all of the plurality of first wireless terminals under the desired first base station. Therefore, the slot is not allocated to all the first wireless terminals, and a useless empty slot is generated. Accordingly, the cell throughput may be reduced. Note that, for example, the above two problems are exactly the same even when the method disclosed in Patent Document 3 is applied to mobile communication.

  Further, the method of the second embodiment disclosed in Patent Document 1 is a method that does not perform inter-base station cooperation of the first embodiment, and a C / I estimation method on the wireless terminal side is used. It is a changed method. The C / I is estimated by averaging the interference power when the interference received from adjacent cells is large and small, and the downlink transmission rate is selected. Therefore, in the slot allocated to the radio terminal, when the interference is small, there is a possibility that a low rate is transmitted even though the reception quality is good. On the other hand, when the interference is large, the reception quality is deteriorated. Packet loss may occur. Therefore, the throughput of the wireless terminal may decrease. In addition, radio resources may not be used effectively.

  In the system disclosed in Patent Document 4, beam scheduling information indicating in which direction the beam is directed is shared between base stations. On the wireless terminal side, the amount of interference from each beam pattern radiated by the adjacent cell is estimated, and all the amount of interference is reported to the base station. The scheduler of the base station estimates the presence / absence of interference and the downlink reception quality in that case based on the information, and determines the downlink transmission rate on the base station side, so that the data rate corresponding to the presence / absence of interference is determined. It becomes possible to select. However, for example, there are the following problems.

  First, since the interference amount of the adjacent cell reported from the wireless terminal side does not know which beam causes interference in the slot for transmitting downlink data, all interference information is reported. Therefore, the amount of uplink feedback information is large, and there is a possibility of reducing the uplink data line capacity. Second, in order to select the downlink data rate on the base station side, the wireless terminal side needs to have a plurality of demodulation circuits so that demodulation of all transmission rates is possible, which may increase the circuit scale. is there.

  In view of the above points, the present invention prevents wireless communication from being reduced as a result of interference avoidance under application of the inter-base station cooperation method, and enables wireless communication with an appropriate downlink transmission rate even in an interference occurrence slot. It aims to provide a method. In addition, the present invention suppresses an increase in the amount of uplink feedback information and allows the demodulation circuit scale of the wireless terminal to be small even when communication is performed at an appropriate downlink transmission rate in the interference occurrence slot under the inter-base station cooperation scheme. An object of the present invention is to provide a wireless communication method and a wireless communication system.

  It is another object of the present invention to perform communication using a data rate corresponding to the interference situation even if the interference situation fluctuation occurs for each slot. Furthermore, an object of the present invention is to improve the reduction in throughput caused by this.

One configuration of a wireless communication method / system provided by the present invention includes, for example, one or more wireless terminals and a base station device, and the base station device includes:
Step 1 of multiplexing and transmitting individual pilot signals using a directivity pattern for each beam area;
In the wireless terminal, receiving a dedicated pilot signal for each beam area of a desired base station, setting a beam area with the highest received power as a desired wave beam area, and requesting the base station as a desired beam area;
Similarly, in the wireless terminal, the dedicated pilot signal for each beam area of each adjacent sector of the same base station and the dedicated pilot signal for each beam area of the base station of the adjacent cell are received, and the beam area with the lowest reception power is received. When an interference component is used, an individual pilot signal in the desired wave beam area is set as S, and a downlink data rate request value based on S / I (desired signal to interference signal power ratio) when the interference component is set as I. Step 3 for selecting (DRC);
The base station shares beam scheduling information indicating which beam pattern is used to transmit each other's transmission with the scheduler of the other sector and the base station of the adjacent cell, so that interference does not occur in each of the plurality of radio terminals. Step 4 to adjust the beam schedule as follows:
In the case where there is no beam schedule in which interference does not occur due to the arrangement of a specific wireless terminal in spite of the adjustment, in order to avoid the throughput reduction of the wireless terminal in which the interference may occur, the wireless terminal in which interference occurs Scheduling user data to step 5;
In the base station, when scheduling is performed such that interference does not occur, the downlink data rate requested by the wireless terminal is selected on the assumption that interference does not occur, and scheduling is performed such that interference occurs. Is a step 6 of converting to a short packet format with a reduced amount of transmission data and selecting a data rate with a reduced error rate, based on the downlink data rate requested by the wireless terminal on the assumption that no interference occurs,
Step 7 of modulating and transmitting downlink data from the base station according to the selected data rate
One of the features is to include.

According to the solution of the present invention,
A wireless communication method in a wireless communication system comprising first and second base stations having a plurality of beam areas, wherein the first and second base stations communicate with a wireless terminal using a beam pattern for each beam area. And
A first base station receiving an identifier of a desired wave beam area selected by a wireless terminal, an identifier of a first interference beam area, and a data rate requested by the wireless terminal from the wireless terminal;
The first base station assigns a beam pattern to each slot and creates first beam scheduling information in which an identifier of the beam pattern is associated with each slot;
The first base station obtains second beam scheduling information in which the identifier of the beam pattern used by each second base station in each slot is associated with each slot;
For the desired slot, the first base station does not match the first identifier of the beam pattern corresponding to the slot of the second beam scheduling information with the second identifier of the received first interference beam area. Selecting a wireless terminal or selecting a wireless terminal in which the first identifier and the second identifier match; and
The first base station selects a first packet format corresponding to a received data rate in a slot in which a wireless terminal whose first identifier and the second identifier do not match is selected, and the first identifier Selecting a second packet format in which the amount of data transmitted in the slot is reduced with respect to the received data rate;
The first base station modulates data according to the selected first and second packet formats, and uses the beam pattern of the desired wave beam area of the selected wireless terminal to transmit the modulated data to the wireless terminal. A wireless communication method is provided.

According to the present invention, it is possible to provide a radio communication method capable of preventing a throughput from being lowered as a result of interference avoidance and performing communication at an appropriate downlink transmission rate even in an interference occurrence slot under application of an inter-base station cooperation scheme. Can do. In addition, according to the present invention, even when communication is performed at an appropriate downlink transmission rate in an interference occurrence slot under application of the inter-base station cooperation method, an increase in the amount of uplink feedback information is suppressed, and the demodulation circuit scale of the wireless terminal is small. A wireless communication method / system that can be accommodated can be provided.
According to the present invention, communication can be performed using a data rate corresponding to an interference situation even if an interference situation fluctuation occurs for each slot. Therefore, it is possible to improve the decrease in throughput due to this.

Hereinafter, although this embodiment is described with reference to drawings, the present invention is not limited to this embodiment.
FIG. 2 is a configuration diagram of the wireless communication system in the present embodiment.
The wireless communication system includes, for example, at least two base stations (201-1, 201-2) and a plurality of wireless terminals (211-1, 211-2, 211-3). In the figure, two base stations and three wireless terminals are shown, but more or less of each may be provided. When there are three or more base stations, it can be considered that each of the plurality of base stations is configured in pairs. In the example of FIG. 2, the wireless terminals 211-1 and 211-2 are connected to a first base station 201-1 (hereinafter referred to as AP 1), and the wireless terminal 211-3 is connected to a second base station 201. -2 (hereinafter referred to as AP2). Each base station 201 forms a plurality of beam areas 221 to 224 and 231 to 234, and when transmitting user data to the wireless terminal 211 in a time-sharing manner, each of the beam areas suitable for the direction in which the wireless terminal is located. User data is transmitted in a radiation beam pattern. In addition to the illustration, the beam areas can be formed from the base station in all directions, for example. Further, for example, sectors each having a plurality of beam patterns may be provided. A plurality of beam patterns may be transmitted from the base station in the same slot using a radiation pattern including a plurality of beam patterns.

  Each of the base stations AP1 (201-1) and AP2 (201-2) receives beam schedule information when scheduling the user data, that is, information indicating which radiation beam pattern is used in which slot, Sharing via the network line (241). The database for storing the beam schedule information may be in each base station, or a shared database may be arranged on the network and managed by the database, or another appropriate method may be used.

  AP1 (201-1) forms, for example, beam areas 1 (221), 2 (222), 3 (223), and 4 (224). AP2 (201-2) forms, for example, beam areas 1 (231), 2 (232), 3 (233), and 4 (234). The wireless terminal 211-1 is located in the range of the beam area 3 (223) of the AP1 (201-1) and receives the interference of the beam 3 (233) of the AP2 (201-2). The wireless terminal 211-2 is located in the range of the beam area 2 (222) of AP1 (201-1) and receives interference from the beam 2 (232) of AP2 (201-2). The wireless terminal 211-3 is located in the range of the beam area 3 (233) of AP2 (201-2), and receives the interference of the beam 3 (223) of AP1 (201-1). Note that each beam area may receive a considerable amount of interference from other than the above-described beams, but in this embodiment, for convenience of explanation, there is a case where no interference occurs or there is no interference.

FIG. 1 is a sequence diagram of the present embodiment.
The figure shows the passage of time from top to bottom. In the figure and the following description, attention is given to AP1 (201-1), AP2 (201-2), and wireless terminal 211-1 (hereinafter referred to as AT1). However, as a matter of course, the effect of the present invention does not depend on the number of base stations. The wireless terminals 211-2 and 211-3 also have the same sequence, except that the base station or beam area to be connected is different from that of AT1.

  Each base station (AP1, AP2) transmits a unique individual pilot signal for each beam area (101, 102). For example, the individual pilot signal includes identification information (for example, a Walsh orthogonal code) for identifying a base station and a beam area.

  AT1 (211-1) selects an area and obtains a communication rate (103). For example, the AT1 (211-1) measures the reception level of each individual pilot signal transmitted from the AP1 (201-1) to which the AT1 (211-1) is connected. It is recognized as a beam area (desired wave beam area). It should be noted that a desired wave beam area having a reception level equal to or higher than a predetermined threshold may be used. In the case of AT1 (211-1) in FIG. 1, the beam area 3 (223) of AP1 (201-1) corresponds. Next, the reception level of each individual pilot signal transmitted from AP2 (201-2) adjacent to AP1 (201-1) is measured. Here, the beam having the highest reception level of the beam from the adjacent AP 2 is set as the first interference beam area. In the case of AT1 (211-1) in FIG. 1, the beam area 3 (233) of the adjacent base station AP2 (201-2) corresponds. Note that one having a reception level equal to or higher than a predetermined threshold value may be selected as the first interference beam area.

  Note that the AT1 (211-1) may consider the base station (201-1) to which it is connected as the desired wave beam area that has the highest received power of each received pilot signal. Also, the first interference beam having the highest received power or a predetermined threshold value or more other than the beam area of the base station (201-1) in the desired wave beam area without being conscious of the adjacent base station. It may be an area.

  Here, in the conventional wireless communication technology that does not perform beam forming, the interference power is a single power output from the adjacent base station, so that C / when the desired wave power is C and the interference wave power is I DRC was estimated from I.

  On the other hand, in the present embodiment, the second interference beam area is selected from the beam areas of adjacent AP2 (201-2) other than the first interference beam area, and the power of the selected second interference beam area is selected. Is the interference wave power I, and DRC is estimated from C / I when the desired wave power is C and the interference wave power is I. For example, AT1 (211-1) has received power of the dedicated pilot signal other than the beam area (221 to 224) of the base station (201-1) in the desired wave beam area, and the dedicated pilot in the first interference beam area. The beam area that is the second largest (that is, the second largest) beam after the received signal power is set as the second interference beam area. In addition, AT1 (211-1) is one of the minimum or corresponding ones of the reception power of the dedicated pilot signal that is not less than a predetermined threshold value except for the beam area of the base station in the desired wave beam area. The beam area may be the second interference beam area. AT1 (211-1) is a beam area (231 to 234) of the base station (201-2) of the first interference beam area, and the beam directing direction is the first interference beam area ( For example, among a plurality of beam areas (for example, the beam areas 232 to 234 in FIG. 1) within a predetermined angle from the directivity direction of the beam area 233 in FIG. An interference beam area may be used.

  The information indicating that it is located under the beam area 3 (223) of the base station AP1 to which it is connected (the local station area number and the desired wave beam area identifier) and the beam area 3 (233) of AP2 are interference power. Information (interference area number, first interference beam area identifier) and request the DRC value to the desired base station AP1 (201-1) (104).

  On the other hand, when AP1 receives the downlink packet data for the AT from the network (105), it temporarily buffers the data (106). Next, beam scheduling for which beam area is to be transmitted is performed, and beam scheduling information is shared with the adjacent base station (108). For example, AP1 assigns a beam pattern to each slot, and creates first beam scheduling information in which an identifier of the beam pattern is associated with each slot. In addition, AP1 shares beam scheduling information with AP2, thereby acquiring second beam scheduling information in which the identifier of the beam pattern used by AP2 in each slot is associated with each slot.

  From the beam scheduling information of the adjacent base station, it is determined whether the scheduled wireless terminal receives interference from the adjacent base station. If the interference is received, conversion to the short packet format is performed (109). Specifically, in the case of the arrangement as shown in FIG. 2, AP1 (201-1) has AT1 (211-1) located under beam area 3 (223) and the beam area of adjacent AP2 (201-2). 3 (233) is known to be an interference by a report from AT1 (211-1) in the process 104. Therefore, AT1 (211-1) is scheduled to be scheduled in a slot in which AP2 (201-2) does not schedule beam area 3 (233). Here, in the conventional wireless communication technology in which beam schedule information is shared between base stations, there is no slot in which interference does not occur under conditions where all slots cause interference. I couldn't do it. If scheduling is assigned to the AT even under conditions where all slots cause interference, packet loss occurs due to interference. In this embodiment, if there is interference, the amount of transmission data is reduced. It is possible to improve the packet loss rate by converting to the short packet format and transmitting.

  That is, the desired base station AP1 (201-1) shares scheduling information with the adjacent base station AP2 (201-2) (108), and the beam 3 (233) in which the AT1 (211-1) receives interference is AP2 In the slot transmitted from (201-2), transmission is performed after converting to the short packet format. When beam 3 (233) is not transmitted, transmission is performed in the normal format with the data rate request value (DRC). Do. Then, the packet data is modulated in accordance with the selected transmission format, and the downlink packet is transmitted (110). The AT1 (211-1) uses the data packet that has been successfully demodulated (111). As a result, it is possible to avoid a significant decrease in the scheduling rate when interference occurs, and to improve the packet loss rate by selecting an appropriate rate and obtain an appropriate throughput.

FIG. 3 is a diagram showing an image of beam schedule information shared by adjacent base stations in the present embodiment.
That is, FIG. 2 is a diagram showing an image of information shared by adjacent base stations in step 108 in the sequence diagram of FIG. The figure shows the passage of time from left to right. The slot time (321) is a slot number (322) incremented by 1 for each slot from left to right. For example, in CDMA2000 1xEV-DO, in the standard of Non-Patent Document 1, the cumulative slot time when 0:00:00 on January 6, 1980 is set as slot 0 is defined as the CDMA system time. Alternatively, this may be a relative slot number that circulates in a predetermined number of slots, for example, 600 slots. In any case, the time unit can be synchronized between adjacent base stations. One slot corresponds to about 1.666 ms, for example.

  The shared beam schedule information stores the identification information of the beam area to which each base station assigns corresponding to the slot time. In the example of FIG. 3, the first beam scheduling information (311-1) for each slot assigned by AP1 (201-1) is the beam area 2 every other slot from time (N-2) to (N + 2). An example is shown in which (222) is scheduled and beam area 3 (223) is scheduled every other slot from time (N-1) to (N + 3). The second beam scheduling information (311-2) for each slot assigned by AP2 (201-2) schedules beam area 3 (233) from time (N-2) to (N + 3). An example is shown.

  Here, consider (N + 1) slots. The slot of (N + 1) schedules beam area 3 (233) in AP2 (201-2). This is because in the example of FIG. 2, only the wireless terminal connected to AP2 (201-2) is AT3 (211-3) under beam area 3 (233). In AP1 (201-1), either beam area 3 (223) where AT1 (211-1) is located or beam area 2 (222) where AT2 (211-2) is located can be selected. Under this condition, AT2 (211-2), that is, beam area 2 (222) is selected in the conventional wireless communication technology that schedules wireless terminals by sharing schedule information. Because, when AT1 (211-1) is selected, beam 3 (223) of AP1 (201-1) and beam 3 (233) of AP2 (201-2) interfere with each other. This is because they are not selected. Then, for example, in such an example of the situation, there is a problem that the allocation of AT1 (211-1) does not occur forever and the throughput is significantly reduced.

  However, this embodiment is different. In the present embodiment, AT1 (211-1) can be allocated even in (N + 1) slots in which interference occurs. Because in (N + 1) slots where interference occurs, the packet loss rate is improved by converting to a short packet and transmitted, avoiding a significant decrease in throughput even under interference, and communication at an appropriate downlink transmission rate. This is because it becomes possible. In addition, the beam area of the other base station which interferes can be discriminate | determined by comparing the beam schedule information shared and the interference area number transmitted from a terminal.

FIG. 4 is a diagram showing elements of feedback information that the wireless terminal reports and requests to the base station in the present embodiment.
That is, the information transmitted from the wireless terminal to the base station in step 104 in the sequence diagram of FIG. The information includes, for example, three elements. That is, the area number (desired wave beam area identifier) (401-1) of the base station to which it is connected, the interference area number (identifier of the first interference beam area) (401-2) of the adjacent base station, and In addition, a downlink transmission rate request value (401-3) on the premise of no interference is included. In the example in which AT1 (211-1) shown in FIG. 2 reports to AP1 (201-1), the area number (401-1) of the base station to which it is connected is the beam area 3 of AP1 (201-1). (223), the interference area number (401-2) of the adjacent base station indicates the beam area 3 (233). An appropriate identifier other than the number may be used.

FIG. 5 is a configuration diagram of the base station (201-1) of the present embodiment.
The base station (201-1) includes, for example, an array antenna (520), a high frequency unit (521), an uplink beam control unit (RLBF) (504), a demodulator (DEM) (505), and downlink beam control. Unit (FLBF) (508), a modulator (MOD) (509), a scheduler unit (SCHED) (510), and a network interface unit (NW) (511). The array antenna (520) has a plurality of antenna elements (501). The high frequency unit (521) includes a duplexer (DUP) (502), a reception side high frequency circuit (RX) (503), and a transmission side high frequency circuit (TX) (507).

  First, the uplink in the base station (201-1) will be described. The uplink signal from the wireless terminal (211) is received by the antenna element (501) of the array antenna (520), passes through the duplexer (DUP) (502) of the high frequency unit (521), and receives on the receiving side high frequency circuit (RX) ( 503). The duplexer (DUP) (502) separates the uplink reception signal and the downlink transmission signal, and includes, for example, a band selection filter that selects each signal. The receiving high-frequency circuit (RX) (503) amplifies the signal from the antenna element (501), converts the frequency to a predetermined sensitivity, and then converts it to a digital signal by an A / D converter.

  The array antenna (520) includes a plurality of antenna elements (501). For example, when a 12-element array antenna is used, the array antenna (520) includes 12 antenna elements (501). When a 12-element array antenna is used, the duplexer (DUP) (502) of the high-frequency unit (521), the reception-side high-frequency circuit (RX) (503), and the transmission-side high-frequency circuit (TX) (507) are also included in each array antenna. Corresponding to 12 each. Accordingly, in this case, the uplink beam control unit (RLBF) (504) receives the uplink signals from the respective antenna elements (501) from the 12 reception high-frequency circuits (RX) (503). Further, the downlink beam control unit (FLBF) (508) outputs a downlink signal to the twelve transmission-side high frequency circuits (TX) (507).

  The uplink beam control unit (RLBF) (504) receives uplink signals from the 12 reception high-frequency circuits (RX) (503), and individually generates uplink beam coefficients for a plurality of radio terminals (211). By combining 12 uplink signals in vector, reception is performed in a direction suitable for each wireless terminal (211). Alternatively, the uplink beam control unit (RLBF) (504) combines and receives 12 uplink signals as omni patterns with the same beam coefficient for a plurality of radio terminals (211). The uplink beam control unit (RLBF) (504) outputs the uplink signal synthesized by any of the above methods to the demodulator (DEM) (505).

  The demodulator (DEM) (505) demodulates the uplink signal for each wireless terminal (211) using a built-in despreader, RAKE combiner, decoder, or the like. Further, the upstream data signal is input to the network interface unit (NW) (511) and transmitted to the network. Further, the demodulator (DEM) (505) has its own station area selection number (401-1), interference area number (401-2), and data rate request value DRC (401-) included in the demodulated uplink signal. 3) That is, a set of wireless terminal feedback information (401) is output to the scheduler unit (SCHED) (510). The wireless terminal feedback information (401) input to the scheduler unit (SCHED) (510) is used for the downlink scheduling operation described later. This completes the explanation of the uplink.

Next, the downlink in the base station (201-1) will be described.
FIG. 7 shows a detailed block diagram of the scheduler unit (SCHED) (510). FIG. 9 shows a flowchart of the scheduler. The flow in FIG. 9 corresponds to the processes 107 to 109 in the sequence in FIG.

  The scheduler unit (SCHED) (510) includes, for example, a beam scheduler unit (BM_SCHED) 701, a terminal scheduler unit (AT_SCHED) 702, a terminal management table (AT_TBL) 703, an interference determination table (I_TBL) 704, and a data buffer. (DATA_BUF) 705, a short packet conversion table (SH_TBL) 706, a data selector 707, and an adjacent station beam scheduling information table (BM_SCHED_TBL) 708.

  The downlink data signal input from the network by the network interface unit (NW) (511) is input to the scheduler unit (SCHED) (510) and held in the data buffer (DATA_BUF) (705). Among the feedback information (401) input from the demodulator (DEM) (505), the local station area selection number (401-1) is registered in the terminal management table (AT_TBL) (703) and the interference area number (401). -2) is registered in the interference determination table (I_TBL) (704), and the data rate request value DRC (401-3) includes a beam scheduler unit (BM_SCHED) (701) and a terminal scheduler unit (AT_SCHED) (702). Is input.

  In the beam scheduler unit (BM_SCHED) (701), a terminal to be allocated in the future is estimated over several slots, and a beam direction (beam pattern) in which the terminal physically exists is reserved in advance for each slot (S101). For example, the beam scheduler unit (701) first calculates the scheduling evaluation value of each wireless terminal (211) based on the DRC value input from the demodulator (DEM) (505). For example, the average downlink rate R for each wireless terminal (211) is obtained, and DRC / R is obtained as an evaluation value based on DRC and R. Note that the downlink average rate R can be obtained based on, for example, the amount of data transmitted within a certain past time. Scheduling is performed so that the evaluation values are equal in each wireless terminal (211). For example, scheduling is performed by preferentially assigning the wireless terminal (211) having the maximum evaluation value to the slot at the present time. Further, the beam scheduler unit (701) refers to the terminal management table (AT_TBL) (703), obtains the beam area (own station area) where the selected wireless terminal (211) exists, and transmits the downlink data signal. The radiation beam pattern of The radiation beam pattern can be selected from a plurality of predetermined beam patterns as shown in FIG. Information for managing the radiation beam pattern number in association with each slot is stored as beam scheduling information (311-1).

  Next, the scheduler unit (SCHED) (510) shares beam schedule information (311-1 and 311-2) with the adjacent base station (201-2) via the network line (241) (S102). The network line (241) may be a dedicated line for the purpose of sharing the beam schedule information (311-1 and 311-2), or a network for communicating uplink / downlink data signals. May be shared. The beam schedule information (311-2) received from the adjacent base station (201-2) is stored in the adjacent station beam scheduling information table (BM_SCHED_TBL) (708). Further, the beam schedule information of the own base station is output from the beam scheduler unit (701) to another base station or an appropriate server, database, or the like.

  The terminal scheduler unit (AT_SCHED) (702) again calculates the scheduling evaluation value of each wireless terminal (211) based on the DRC value input from the demodulator (DEM) (505) (S103). The wireless terminal (211) having the maximum evaluation value is selected (S105). Next, an interference area number is acquired with reference to the interference determination table (I_TBL) (704) of the selected wireless terminal (211). Next, referring to the beam schedule information (311-2) of the adjacent base station from the adjacent station beam scheduling information table (708), whether the schedule area number and the interference area number in the desired slot in the beam schedule information match. Determine (S106). If the area numbers match, it interferes with the adjacent base station, so the selected wireless terminal is removed from the assignment target (deleted from the candidate) (S107), the wireless terminal with the next highest scheduling evaluation value is selected, and the same It is determined whether or not it interferes with an adjacent base station (S104 to S108). If there is no interference, the selection of the wireless terminal is terminated, and the process proceeds to step S111. That is, a wireless terminal that does not interfere is finally selected. On the other hand, if all the wireless terminals interfere with the beam area of the adjacent base station, the wireless terminal having the largest evaluation value is finally selected again (S109).

  In the above-described example, a wireless terminal that does not interfere is preferentially selected. However, even if there is a wireless terminal that does not interfere, a terminal that interferes may be selected. For example, if a wireless terminal that does not interfere is preferentially selected and a slot is not assigned to a specific wireless terminal for a predetermined time or more, the wireless terminal may be selected even if there is interference. For example, the slot interval allocated to the wireless terminal may be monitored. Further, if the slot is not allocated, the average rate R of the wireless terminal is lowered, and therefore, a wireless terminal having a determined scheduling evaluation value (DRC / R) equal to or higher than a predetermined threshold may be selected.

  Here, when the finally selected wireless terminal does not receive interference from the adjacent base station, the data rate request value (DRC) (401-3) input from the demodulation unit (DEM) (505) is used as it is. The downlink transmission rate is determined using it (S111). On the other hand, when receiving interference from an adjacent base station, it is converted into a short packet format and transmitted at a lower downlink transmission rate (S110). For conversion to the short packet format, the short packet conversion table (SH_TBL) (706) is referred to.

FIG. 8 shows an example of a short packet conversion table.
The short packet conversion table (SH_TBL) (706) includes, for example, normal format information (first format information) for transmitting data at the data rate corresponding to the DRC value or identifier, and the data rate. Short packet format information (second format information) for transmitting data at a lower data rate is stored. Each of the first and second format information includes a packet size and a span.

  The short packet format that can be transmitted corresponding to each data rate request value (DRC) is cdma2000 1xEV-DO Rev. Specified in the A standard, the short packet conversion table (SH_TBL) (706) selects from these transmittable formats and selects a receivable rate even when interference occurs. And register in advance. The transmission format is represented by (packet size, span). The packet size represents the number of bits of the physical packet, and the span represents the number of transmission slots. One slot is about 1.666 ms. Here, when the data rate request value DRC is 38.4 kbps, (1024, 16) is a standard format, but it is converted into a short packet and (128, 16), (256, 16), (512). 1024). A format that can reduce the error rate, for example, (256, 16), is selected in advance even when interference from an adjacent base station is received from this format, and is registered in the short packet conversion table (SH_TBL) (706). Keep it. Alternatively, the strength of interference may be determined from the packet error rate, and the short packet format to be selected may be dynamically changed. Further, a table may be prepared for each beam area, and a table corresponding to the strength of interference may be set for each area. In the example of the short packet conversion table shown in FIG. 8, when the data rate request value DRC from the wireless terminal (211) is 38.4 kbps, if it is determined that there is no interference, the normal transmission format (1024, 16) If transmission is performed at a transmission rate of 38.4 kbps and it is determined that there is interference, registration is performed so that transmission is performed at a transmission rate of 9.6 kbps in the transmission format (256, 16).

  Next, the scheduler unit (SCHED) (510) outputs the beam pattern number corresponding to the determined radiation beam pattern to the downlink beam control unit (FLBF) (508). The beam pattern number is not limited to a number, and appropriate information for identifying a beam or beam direction, such as letters and angles, can be used. Also, the scheduler unit (SCHED) (510) has the identification information of the scheduled wireless terminal (211), the transmission format information corresponding to the determined downlink transmission data rate, and the wireless selected by the data selector (707). The downlink data signal for the terminal (211) is output to the modulator (MOD) (509). The data selector (707) converts the data signal into a data size corresponding to the transmission format and outputs the data signal to the modulator (MOD).

  The modulator (MOD) (509) and the downlink beam control unit (FLBF) (508) transmit the dedicated pilot signal toward each beam pattern independently of the downlink data packet transmission. Further, the downlink beam control unit (FLBF) (508) multiplies the individual pilot signal sequence by the Walsh orthogonal code according to the radiation beam pattern number when beam forming the individual pilot signal. This is for identifying which beam pattern the wireless terminal (211) is under. Note that the transmission method of the individual pilot signal is not limited in the present embodiment. For example, each beam pattern may be periodically circulated and transmitted, or may be transmitted simultaneously.

  A modulator (MOD) (509) modulates a downlink data signal by using a built-in encoder, spreader, etc., using an inputted downlink transmission data rate, and generates an individual pilot signal, a MAC (Medium Access Control) signal, and the like. It is time-division multiplexed and output to the downlink beam control unit (FLBF) (508).

  The downlink beam control unit (FLBF) (508) uses the radiation beam pattern number input from the scheduler unit (SCHED) (510) to convert the downlink data signal time-division multiplexed by the modulator (MOD) (509). Beam forming. Those signals formed by the downlink beam control unit (FLBF) (508) are twelve downlink signals, which are respectively output to the twelve transmitting high-frequency circuits (TX) (507). Each high-frequency circuit (TX) (TX) on the transmission side performs amplification, frequency conversion, and the like after the downstream signal input from the downstream beam control unit (FLBF) (508) is converted into an analog signal by a D / A converter. The transmission-side high-frequency circuit (TX) (507) outputs the converted downlink signal to the antenna element (501) constituting the array antenna (520) via the duplexer (DUP) (502). A signal is radiated from the antenna element (501). This completes the description of the downlink.

FIG. 6 shows a configuration diagram of the wireless terminal (211).
The wireless terminal (211) includes, for example, an antenna unit (601), a duplexer (DUP) (602), a receiving high-frequency circuit (RX) (603), a demodulator (DEM) (604), and reception quality measurement. Unit (607), DRC estimation unit (608), area measurement unit (609), transmission-side high-frequency circuit (TX) (610), modulator (MOD) (611), and PC interface unit (620) With.

  First, the downlink in the wireless terminal (211) will be described. The downlink signal from the base station (201-1) is received by the antenna unit (601), passes through the duplexer (DUP) (602), and is input to the reception high-frequency circuit (RX) (603). The receiving high-frequency circuit (RX) (603) amplifies the input downstream signal, converts the frequency to a predetermined sensitivity, converts it to a digital signal by an A / D converter, and demodulates (DEM) ( 604). The demodulator (DEM) (604) demodulates the downlink signal by a built-in despreader, RAKE synthesizer, etc., and separates it into a downlink data signal before decoding, individual pilot signal, MAC signal, etc. that are time-division multiplexed. To do. The downlink data signal is decoded in both the required data rate format (DRC) and the short packet format, and the downlink data signal that has been successfully decoded is output to the PC interface unit (PC) (602), and is sent to the upper layer. Send. Note that whether or not decoding has been successful can be determined by a CRC (Cyclic Redundancy Check), that is, a cyclic redundancy check method. Since this determination method is a general method, description thereof is omitted here. Note that it may be determined whether the decryption has been successfully performed by another method. The demodulator (DEM) (604) outputs the separated individual pilot signals to the area measurement unit (609) and the reception quality measurement unit (607), respectively.

  Based on the Walsh orthogonal code and the received power level of each input individual pilot signal, specifically, each individual pilot signal transmitted by the base station AP1 (201-1) to which the area measurement unit (609) is connected, It is determined which beam area of the base station AP1 (201-1) to which it is connected and is output to the modulator (MOD) (611) as its own station area selection number (401-1). Further, the area measurement unit (609), based on the input individual pilot signal, specifically, the Walsh orthogonal code and the reception power level of each individual pilot signal transmitted by the adjacent base station AP2 (201-2), It is determined from which beam area of the adjacent base station AP2 (201-2) the interference is received, and the interference area number (401-2) is output to the modulator (MOD) (611). For example, which beam area of which base station is an individual pilot signal transmitted can be determined by a Walsh orthogonal code.

  In addition, the reception quality measurement unit (607) is configured so that each input individual pilot signal, specifically, the base station AP1 (201-1) to which it is connected and the adjacent base station AP2 (201-2) are connected to each other. Each reception quality (for example, C / I) of each individual pilot to be transmitted is measured. Among the interferences received from the adjacent base station AP2 (201-2), the individual pilot signal power of the beam area showing the most significant interference is not included in the I component (interference component), and other individual pilot signal powers are included in the I component. C / I is measured and output to the DRC estimation unit (608). Based on the received reception quality (C / I), the DRC estimation unit (608) estimates the data rate requirement value (DRC) most suitable for the downlink when C / I is assumed, and the modulator (MOD) ) (611).

  Next, the uplink in the wireless terminal (211) will be described. The uplink data signal from the upper layer is input to the modulator (MOD) (611) through the PC interface unit (620). The modulator (MOD) (611) receives the uplink data signal, the downlink data rate request value DRC (401-3) output from the DRC estimation unit (608), and the output from the area measurement unit (609). The station area selection number (401-1) and the interference area number (401-2) are code-multiplexed, further encoded / spread, and modulated to generate an uplink signal. The transmitting high-frequency circuit (TX) (610) receives the upstream signal generated by the modulator (MOD) (611), converts it to an analog signal by a built-in D / A converter, and performs amplification, frequency conversion, etc. Do. The converted signal passes through the duplexer (DUP) (602) and is radiated from the antenna unit (601).

  According to the present embodiment, for example, even when all the plurality of second wireless terminals under the second base station of the adjacent cell are distributed in the direction of the first wireless terminal connected to the desired first base station, the first The base station can assign a slot to the first wireless terminal. Therefore, it is possible to prevent a state in which the first wireless terminal cannot communicate at all, and it is possible to prevent an extreme decrease in throughput.

  Also, consider a case where all of a plurality of first wireless terminals under a desired first base station are distributed in the direction of one second wireless terminal under a second base station of an adjacent cell. Even in the slot in which the second base station of the adjacent cell sends user data with directivity to the second wireless terminal, it is possible to allocate the slot to the first wireless terminal, thereby reducing wasted empty slots. it can. Therefore, an extreme decrease in cell throughput can be prevented.

  Furthermore, the interference amount of the adjacent cell reported from the wireless terminal side does not have to report all the interference information, and therefore it is possible to suppress an increase in uplink feedback information amount. In addition, since the wireless terminal side can demodulate all transmission rates, it is not necessary to have a plurality of demodulation circuits, and an increase in circuit scale can be prevented.

  INDUSTRIAL APPLICABILITY The present invention can be used, for example, in a base station that performs cellular communication, an array antenna type wireless device including a plurality of antennas, a base station that forms a beam in a time division manner and transmits a packet, and an industry related to a wireless communication system. .

The flowchart of embodiment. The system block diagram of embodiment. The scheduling information sharing image figure of embodiment. The radio | wireless terminal feedback information element figure of embodiment. The block diagram of the base station apparatus of embodiment. The block diagram of the radio | wireless terminal of embodiment. The block diagram of the scheduler part of embodiment. The short packet conversion table example of embodiment. The scheduling flowchart of embodiment.

Explanation of symbols

101 Individual pilot signal 102 of multiple beam areas transmitted by AP2 Individual pilot signal 103 of multiple beam areas transmitted by AP1 Area selection and communication rate selection performed by AT 104 Local area selection / interference area report and communication rate request from AT 105 Downlink packet data transfer from NW 106 Data queuing at AP 108 Beam scheduling information sharing operation 109 Interference determination and short packet conversion 110 Downstream packet transmission 111 Data demodulation 201-1 Desired base station AP1
201-2 Interfering base station AP2
211-1, 2, wireless terminals AT 1 and 2 under AP 1
211-3 Wireless terminal AT3 under AP2
221 to 224 AP1 beam areas 1 to 4
231 to 234 AP2 beam areas 1 to 4
241 Schedule information sharing network line 311-1 Beam scheduling information for each slot of AP1 311-2 Beam scheduling information for each slot of AP2 321 Slot time 322 Unique slot time given for each slot 401 Wireless terminal feedback information 401-1 Station area number 401-2 Other station interference area number 401-3 Downlink data rate value (DRC) assuming no interference
501 Antenna element 502 Duplexer (DUP)
503 High-frequency circuit on receiving side (RX)
504 Uplink beam control unit (RLBF)
505 Demodulator (DEM)
507 Transmitter high frequency circuit (TX)
508 Downlink beam control unit (FLBF)
509 Modulator (MOD)
510 Scheduler (SCHED)
511 Network interface unit (NW)
520 Array antenna 521 High-frequency unit 601 Antenna unit 602 Duplexer (DUP)
603 High-frequency circuit on receiving side (RX)
604 Demodulator (DEM)
607 Reception quality measurement unit 608 DRC estimation unit 609 Area measurement unit 610 Transmission-side high-frequency circuit (TX)
611 Modulator (MOD)
620 PC interface unit (PC)
701 Beam scheduler unit (BM_SCHED)
702 Terminal scheduler unit (AT_SCHED)
703 Terminal management table (AT_TBL)
704 Interference determination table (I_TBL)
705 Data buffer (DATA_BUF)
706 Short packet conversion table (SH_TBL)
707 Data selector 708 Neighboring station beam scheduling information table

Claims (9)

A wireless communication method in a wireless communication system comprising first and second base stations having a plurality of beam areas, wherein the first and second base stations communicate with a wireless terminal using a beam pattern for each beam area. And
A first base station receiving an identifier of a desired wave beam area selected by a wireless terminal, an identifier of a first interference beam area, and a data rate requested by the wireless terminal from the wireless terminal;
The first base station assigns a beam pattern to each slot and creates first beam scheduling information in which an identifier of the beam pattern is associated with each slot;
The first base station obtains second beam scheduling information in which the identifier of the beam pattern used by each second base station in each slot is associated with each slot;
For the desired slot, the first base station does not match the first identifier of the beam pattern corresponding to the slot of the second beam scheduling information with the second identifier of the received first interference beam area. Selecting a wireless terminal or selecting a wireless terminal in which the first identifier and the second identifier match; and
The first base station selects a first packet format corresponding to a received data rate in a slot in which a wireless terminal whose first identifier and the second identifier do not match is selected, and the first identifier Selecting a second packet format in which the amount of data transmitted in the slot is reduced with respect to the received data rate;
The first base station modulates data according to the selected first and second packet formats, and uses the beam pattern of the desired wave beam area of the selected wireless terminal to transmit the modulated data to the wireless terminal. And a step of transmitting. Each of the first and second base stations transmits a pilot signal using a beam pattern for each beam area;
The radio terminal receives each pilot signal for each beam area from the first base station, and the radio terminal has the largest received power of the pilot signal or the beam area in which the received power is equal to or greater than a predetermined threshold. A step with one desired wave beam area,
The wireless terminal receives each pilot signal for each beam area from the second base station, and selects one of the beam areas having the largest received power of the pilot signal or the beam area having the received power equal to or greater than a predetermined threshold. Making the first interference beam area and one of the beam areas other than the first interference beam area a second interference beam area;
The wireless terminal obtains a data rate required for the base station based on a ratio between the received power of the pilot signal in the desired wave beam area and the received power of the pilot signal in the second interference beam area;
2. The wireless communication according to claim 1, further comprising the step of transmitting the identifier of the desired wave beam area, the identifier of the first interference beam area, and the obtained data rate to the first base station. Method. The step of selecting the wireless terminal includes
For the desired slot, the first base station does not match the first identifier of the beam pattern corresponding to the slot of the second beam scheduling information with the second identifier of the received first interference beam area. When there is a wireless terminal, the wireless terminal is selected, and when there is only a match between the first identifier and the second identifier, or a wireless terminal where the first identifier and the second identifier do not match The wireless communication method according to claim 1, wherein when a specific wireless terminal is not selected for a predetermined slot by selecting, the wireless terminal with the same identifier is selected.   The wireless communication method according to claim 1, wherein the second packet format is a short packet format determined in advance corresponding to the data rate. Selecting the packet format comprises:
First packet format information including a first packet size and a first span for the first base station to transmit data at the data rate corresponding to a data rate value or identifier; and the data A second packet size for transmitting data at a data rate lower than the rate and short packet information including a second span is stored, and the second beam pattern identifier and the second packet pattern are stored. Obtaining first packet format information or short packet format information corresponding to the received data rate in response to matching and mismatching of identifiers of one interference beam area;
Transmitting to the wireless terminal comprises:
The wireless communication method according to claim 1, further comprising modulating data according to the acquired first packet format information or short packet format information. The step of selecting the wireless terminal includes
The first base station
For each wireless terminal, determining the data rate of the wireless terminal based on the amount of data already transmitted to the wireless terminal;
For each wireless terminal, obtaining an evaluation value for scheduling by dividing the data rate requested by the wireless terminal by the obtained data rate;
The wireless terminal having the largest evaluation value is judged to match or not match the first and second identifiers, and if there is a wireless terminal that does not match, the wireless terminal is selected. The wireless communication method according to claim 1, comprising selecting one of the wireless terminals that is larger than a predetermined threshold. The step of selecting the wireless terminal includes
The first base station
For each wireless terminal, determining the data rate of the wireless terminal based on the amount of data already transmitted to the wireless terminal;
For each wireless terminal, obtaining an evaluation value for scheduling by dividing the data rate requested by the wireless terminal by the obtained data rate;
The wireless communication method according to claim 1, further comprising: selecting the specific wireless terminal whose evaluation value is equal to or greater than a predetermined threshold value and transmitting data in a short packet format. The first and second base stations each comprise a sector having a plurality of beam areas;
The radio terminal according to claim 2, wherein the radio terminal obtains the first interference beam area and the second interference beam area from sectors other than the sector of the desired wave beam area among the sectors of the first and second base stations. Wireless communication method. The step of setting the second interference beam area includes
(A) A beam area in which the received power of the pilot signal is the second largest next to the received power of the pilot signal in the first interference beam area other than the beam area of the base station in the desired wave beam area, or
(B) Of the beam areas other than the beam area of the base station in the desired wave beam area, where the reception power of the pilot signal is equal to or greater than a predetermined threshold, the beam area with the minimum reception power or one of the corresponding beams Area or
(C) The beam area of the second base station in the first interference beam area, and the beam directing direction is within a predetermined angle from the pointing direction of the first interference beam area. The wireless communication method according to claim 2, further comprising setting any one of the beam areas having the minimum pilot signal reception power as the second interference beam area.

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