JP2012054725A - Base station device and antenna control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a base station device capable of estimating an arrival direction of a signal based on a receiving signal to decide an antenna pattern preferably.SOLUTION: A base station device 1 has a switch 12, a transmission and reception system part 13, a switch controller 15, an RSSI measurement part 32, and a pattern decision part 34. The switch 12 switches over combinations of a plurality of antennas 10 to form a plurality of directivity antenna patterns oriented in different directions or a non-directivity antenna pattern. The switch controller 15 controls the switch 12 to make a signal be received using desired directivity antenna patterns. The RSSI measurement part 32 measures reception strength of each signal received using the directivity antenna patterns. The pattern decision part 34 decides an antenna pattern whose reception strength becomes the maximum based on the measurement result of the reception strength as an antenna pattern to be utilized in communication with a mobile station.

Description

  Embodiments described herein relate generally to a base station apparatus and an antenna control method.

  Conventionally, a wireless communication technique in which a base station apparatus using an adaptive array antenna performs applicable directional communication is known. This wireless communication technique is a technique that is applied to change the antenna directivity main beam in the desired wave direction and the directivity valley (null) in the interference wave direction. For example, a technique is known in which a base station apparatus forms the directivity of an adaptive array antenna based on a signal transmitted from a mobile station using RACH (Random Access CHannel).

  A signal (RACH signal) transmitted using RACH is, for example, at the start of communication in a communication method such as W-CDMA (Wideband Code Division Multiple Access), HSDPA (High Speed Downlink Packet Access), and LTE (Long Term Evolution). This is a signal transmitted from the mobile station to the base station.

JP 2003-158479 A

  When the antenna directivity is formed based on the RACH signal, the base station apparatus estimates the arrival direction of the signal by performing weight calculation based on the RACH signal. When the base station apparatus has a required number of transmission / reception systems, the base station apparatus can perform this weight calculation with a constant quality, and can accurately estimate the direction of arrival. As a result, the base station apparatus can form appropriate antenna directivity.

  However, when a signal having a short packet length, such as a RACH signal, is used, there is a problem that the performance of weight calculation is deteriorated. In addition, when the number of transmission / reception systems provided in the base station apparatus is small due to restrictions on the number of transmission / reception systems, there is a problem in that arrival direction estimation by weight calculation and transmission beam control performance deteriorate. For this reason, when the number of transmission / reception systems is restricted, the base station apparatus cannot form the antenna directivity using the RACH signal, and transmits a signal with non-directionality.

  The present invention has been made in view of such circumstances, and provides a base station apparatus and an antenna control method capable of estimating an arrival direction of a signal based on a received signal and appropriately determining an antenna pattern. Objective.

  The base station apparatus in the embodiment includes a plurality of antennas, a switch, a reception unit, a switch control unit, an RSSI measurement unit, and a pattern determination unit. The switch switches a combination of antennas to form a plurality of directional antenna patterns or omnidirectional antenna patterns that are directed in different directions. The receiving unit receives a predetermined signal transmitted from the mobile station from the antenna. The switch control unit controls the switch to receive a signal using a required directional antenna pattern. The RSSI measurement unit measures the reception intensity of the signal received using the directional antenna pattern. The pattern determining unit determines an antenna pattern having the maximum reception intensity based on the measurement result of the reception intensity as an antenna pattern used for communication with the mobile station.

The functional block diagram which shows embodiment of the base station apparatus which concerns on this invention. The figure which shows especially the structure of the antenna of FIG. The figure which shows an example of the antenna pattern which an antenna forms. The figure which shows the random access procedure of a contention base system. The flowchart explaining the 1st antenna pattern determination process performed by the base station apparatus in this embodiment. The flowchart explaining the 2nd antenna pattern determination process performed by the base station apparatus in this embodiment. The flowchart explaining the 3rd antenna pattern determination process performed by the base station apparatus in this embodiment. The flowchart explaining the 4th antenna pattern determination process performed by the base station apparatus in this embodiment.

  An embodiment of a base station apparatus and an antenna control method according to the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is a functional block diagram showing an embodiment of a base station apparatus according to the present invention.

  FIG. 2 is a diagram specifically showing the configuration of the antenna of FIG.

  The base station apparatus 1 conforms to each method such as W-CDMA (Wideband Code Division Multiple Access), HSDPA (High Speed Downlink Packet Access), and LTE (Long Term Evolution) standardized by 3GPP which is a standardization organization. A communication system is formed between the mobile stations. The base station apparatus 1 can also be applied to a communication system using WiMAX (Worldwide Interoperability for Microwave Access).

  The base station apparatus 1 includes N antennas 10. In the subsequent stage of the antenna 10, a reactance element 14 and a transmission / reception system unit 13 composed of M (N ≧ M) systems are provided. The antenna 10 is connected to the transmission / reception system unit 13 or the reactance element 14 based on switching of the switch 12. Although the transmission / reception system unit 13 is provided with M systems, one of them is particularly illustrated in FIG. The configuration of the antenna may form directivity capable of receiving both polarization planes.

  The switch 12 switches a combination of a feeding antenna element connected to the transmission / reception system unit 13 and a parasitic antenna element connected to the reactance element 14. The switch control unit 15 appropriately controls the switch 12 at the time of RSSI measurement and antenna pattern determination described later. In the present embodiment, the base station apparatus 1 determines the radiation characteristics (antennas) of the antenna 10 according to the combination of the feeding antenna element connected to the transmission / reception system unit 13 and the parasitic antenna element connected to the reactance element 14. The pattern) is changed to form directivity in the antenna 10. One of the plurality of antenna patterns is omnidirectional. That is, the antenna 10 can form a plurality of directional antenna patterns or omnidirectional antenna patterns directed in different directions.

  FIG. 3 is a diagram illustrating an example of an antenna pattern formed by the antenna 10.

  A white circle in FIG. 3 indicates a feeding antenna element, and a black circle indicates a parasitic antenna element. Here, an example is shown in which there are two feeding antenna elements and one parasitic antenna element.

  As shown in FIGS. 3A to 3C, the antenna 10 can form different directivities based on switching of the switch 12.

  The RF unit 21 performs processing such as down-conversion and A / D conversion on the reception signal received via the feeding antenna element, and then outputs the reception signal to the demodulation unit 22. The demodulator 22 demodulates the signal output from the RF unit 21 and outputs the demodulated signal to the rate converter 23. The rate conversion unit 23 converts the coding rate of the signal output from the demodulation unit 22 based on the MCS (Modulation and Coding Scheme) level corresponding to the channel quality indicator (CQI) of the received signal.

  The decoding unit 24 performs decoding processing such as error correction on the rate-converted signal output from the rate conversion unit 23 to obtain received data. The error detection unit 25 performs error detection using the decoded error detection code. In the present embodiment, a CRC (Cyclic Redundancy Check) code is used as the error detection code.

  The reception data processing unit 26 performs necessary processing based on the reception data output from the error detection unit 25. The CRC determination unit 27 determines whether or not decoding has been correctly performed as a result of detecting an error after decoding. The CRC determination unit 27 causes the mobile station to transmit ACK (Acknowledgement, positive response) when it is decoded correctly, and NACK (Negative-Acknowledgement, negative response) when it is decoded erroneously.

  The transmission data generation unit 28 generates necessary data to be transmitted to the mobile station. The encoder 29 performs an encoding process such as error correction encoding on the transmission packet output from the transmission data generator 28 and outputs the result to the rate converter 30. The rate conversion unit 30 converts the coding rate by performing punctured processing or the like on the data subjected to the coding processing in the coding unit 29. The modulation unit 31 performs modulation processing on the data output from the rate conversion unit 30 and outputs the data to the RF unit 21. The RF unit 21 performs predetermined radio transmission processing such as up-conversion on the signal output from the modulation unit 31 and transmits the signal to the base station via the antenna 10.

  The RSSI measurement unit 32 measures an RSSI (Received Signal Strength Indicator) of the received signal demodulated by the demodulation unit 22. In the present embodiment, the RSSI measurement unit 32 is an example of a quality measurement unit that measures reception quality of a signal received using a directional antenna pattern. The storage unit 33 stores the RSSI measurement result obtained by the RSSI measurement unit 32. The pattern determination unit 34 determines an antenna pattern used for communication with the mobile station based on the RSSI measurement result stored in the storage unit 33.

  In general, the base station device 1 uses random access (RA) when performing uplink initial connection with a mobile station. Random access is a system in which initial connection in the uplink is established by RACH (Random Access CHannel) transmitted from a mobile station and settings for starting communication are performed. There are two types of random access: contention-based random access (Contention Based Random Access) that is performed without assigning a dedicated channel to each user, and non-contention based random access (Non-Contention Based Random Access) that assigns a dedicated channel to each user. Has two methods.

  These two methods are used according to the purpose of connection establishment (for example, 3GPP TR 36.300 V9.4.0, “Evolved Universal Terrestrial Radio Access (E-UTRA) and Evolved Universal Terrestrial Radio Access Network (U-UTRAN); description; Stage 2 (Release 9), 10.1.5 Random Access Procedure, (2010-03)) Random access using contention-based method is applied to communication between base station 1 and mobile station An example will be described.

  FIG. 4 is a diagram showing a contention-based random access procedure.

  The random access procedure has four procedures. The mobile station and the base station apparatus 1 transmit and receive messages using RACH in each procedure. The messages are Message 1 (RA Preamble), Message 2 (RA Response), Message 3 (Scheduled Transmission), and Message 4 (Contention Resolution) in order from the first procedure.

  The base station apparatus 1 receives Message 1 from the mobile station that makes the connection request. When the base station apparatus 1 recognizes the mobile station that has normally received Message 1 that is a random access preamble and has made a connection request, it transmits Message 2 that is a random access response to the mobile station as a second procedure. Message 2 transmits RA Preamble identification information, timing adjustment information, initial UL Grant (UL Scheduling Grant), temporary C-RNTI (Cell Specific-Radio Network Temporary Identifier), and the like. The RNTI is a temporary identifier for identifying the user. C-RNTI is a cell-specific temporary user identifier.

  In the scheduled transmission procedure, which is the third procedure, the mobile station transmits Message 3 to the base station apparatus 1. Message 3 transmits identification information of the mobile station, such as the provisional C-RNTI and NAS message described above. HARQ (Hybrid Automatic Repeat reQuest) is applied to Message3. Therefore, the base station apparatus 1 transmits acknowledgment information based on the message decoding result (CRC check result) to the mobile station using the control channel.

  The mobile station performs retransmission control according to the contents of the delivery confirmation information transmitted from the base station apparatus 1. The content of the delivery confirmation information is expressed by either ACK (acknowledgment) or NACK (negative acknowledgment) described above. When the mobile station receives NACK from the base station apparatus 1, the mobile station retransmits Message 3. When the mobile station receives an ACK from the base station apparatus 1, the mobile station proceeds to a fourth procedure.

  In the contention resolution that is the fourth procedure, the base station apparatus 1 transmits Message 4 to the mobile station to establish an uplink.

  The base station apparatus 1 in this embodiment determines an appropriate antenna pattern using the RACH Message 3 to which the above-described HARQ is applied. Hereinafter, the antenna pattern determination process (antenna control method) executed by the base station apparatus 1 will be specifically described.

  FIG. 5 is a flowchart for explaining a first antenna pattern determination process executed by the base station apparatus 1 in the present embodiment.

  In the antenna pattern determination process described below, the process executed after the base station apparatus 1 receives the RACH Message 3 until the Message 4 is transmitted will be particularly described, and the description of the transmission / reception process of the Message 1 and Message 2 will be omitted. . The same applies to the second to fourth antenna pattern determination processes described below.

  In step S <b> 1, the base station apparatus 1 switches the switch 12 based on the control of the switch control unit 15 to form an omnidirectional antenna pattern and receives Message 3. In step S <b> 2, the base station apparatus 1 determines whether or not Message 3 has been normally received by the CRC determination unit 27. When the base station apparatus 1 determines that Message 3 is not normally received (CRC determination: No), in step S3, the base station apparatus 1 transmits NACK as HARQ delivery confirmation information to the mobile station, and retransmits Message 3 from the mobile station. Await. In this embodiment, NACK is a retransmission request signal that requests a mobile station to retransmit a signal.

  On the other hand, when the base station apparatus 1 determines that Message 3 has been normally received (CRC determination: Yes), the RSSI measurement unit 32 measures the RSSI of Message 3 from the received signal in step S4. The RSSI measurement unit 32 stores the measurement result in the storage unit 33.

  In step S5, the base station apparatus 1 receives Message 3 in all antenna patterns in which the antenna 10 forms directivity, and determines whether RSSI has been measured. If the base station apparatus 1 determines that the RSSI measurement is not performed for all antenna patterns, the message 3 is still received by switching the switch 12 based on the control of the switch control unit 15 in step S6. Change to an antenna pattern that is not. Thereafter, the process proceeds to a NACK transmission step S3, and the base station apparatus 1 transmits a NACK to the mobile station.

  Here, the base station apparatus 1 transmits NACK to the mobile station and requests retransmission of Message3 even if it is determined that Message3 has been normally received in CRC determination step S2. The base station apparatus 1 repeatedly transmits NACK until Message 3 is received by all antenna patterns. That is, the reception step S1 to the pattern change step S6 are repeated until it is determined in the measurement determination step S5 that the RSSI of Message3 is measured for all antenna patterns.

  When the base station apparatus 1 determines that the measurement result of RSSI is obtained by receiving Message 3 for all the antenna patterns in the measurement determination step S5, the base station apparatus 1 sets each antenna pattern stored in the storage unit 33 in step S7. Based on the RSSI measurement result, an antenna pattern that maximizes the received signal strength is determined. Note that RSSI measurement results are obtained in the plurality of transmission / reception system sections 13 according to the antenna pattern. In this case, the base station apparatus 1 determines an antenna pattern that maximizes the reception strength by taking the RSSI measurement results of the plurality of transmission / reception system sections 13 into consideration.

  In step S8, the base station apparatus 1 transmits ACK to the mobile station. In this embodiment, the ACK is a delivery confirmation signal indicating that the delivery of the signal has been confirmed to the mobile station, and is transmitted when the reception of Message 3 is completed.

  In step S9, the base station apparatus 1 changes the antenna pattern to the determined antenna pattern by switching the switch 12 based on the control of the switch control unit 15. The base station apparatus 1 transmits Message 4 to the mobile station using the changed antenna pattern.

  The base station apparatus 1 and the antenna control method in this embodiment can determine the directivity of the antenna 10 suitably by this antenna pattern determination process. In particular, when the number of transmission / reception systems of the base station apparatus 1 is restricted (for example, the number of transmission / reception systems is two), weight calculation is performed when a signal with a short packet length such as RACH is used for estimating the arrival direction of a signal from a mobile station. The accuracy of will decrease. On the other hand, the base station apparatus 1 in the present embodiment estimates the direction of arrival of the signal based on the measurement result of the received intensity obtained by sequentially changing the configuration of the antenna 10 used for transmission / reception. Even in a restricted case, an antenna pattern having suitable directivity can be determined. As a result, directivity can be imparted to the transmission beam, and interference caused by a transmission signal from the base station apparatus 1 to an adjacent mobile station can be reduced.

  In addition, when the number of transmission / reception systems is large, the accuracy of estimation of the arrival direction of a signal by weight calculation increases, but the configuration of the base station apparatus 1 becomes complicated. On the other hand, the base station apparatus 1 in the present embodiment can estimate the arrival direction of signals even when the number of transmission / reception systems is small, and can simplify the configuration of the base station apparatus 1.

  Furthermore, the base station apparatus 1 is also effective in that the directivity control of the antenna 10 can be performed while complying with existing standards.

  In addition, the base station apparatus 1 demonstrated the example which receives the signal from a mobile station using all the antenna patterns in the 1st antenna pattern determination process. This is effective when there is no mobile station connected to the base station apparatus 1, but it degrades the communication quality with the connected mobile station when there is a connected mobile station. there is a possibility. Therefore, the base station apparatus 1 performs the second antenna pattern determination process described below, so that even if there is a connected mobile station, the base station apparatus 1 can perform a new uplink without degrading the quality related to the existing communication. The direction of arrival of a signal transmitted from a mobile station attempting to establish a link can be estimated.

  FIG. 6 is a flowchart for explaining the second antenna pattern determination process executed by the base station apparatus 1 in the present embodiment.

  In the second antenna pattern determination process, the base station apparatus 1 waits for an uplink signal from the mobile station using an antenna pattern that forms omnidirectionality or directivity, and moves while being connected to the base station apparatus 1 Suppose a station exists.

  Steps S11 to S14 and Steps S16 to S19 in the second antenna pattern determination process are substantially the same as the reception step S1 to the measurement result storage step S4 and the pattern change step S6 to the transmission step S9 in the first antenna pattern determination process. Therefore, the description is omitted here.

  In step S <b> 15, the base station apparatus 1 receives Message 3 in all selectable antenna patterns among the antenna patterns in which the antenna 10 forms directivity, and determines whether RSSI has been measured. The “selectable antenna pattern” is an antenna pattern having directivity including the direction of a mobile station that is already connected, and having directivity that does not degrade the communication quality of the connected mobile station. It is. For example, a pattern other than an antenna pattern in which a directivity valley (null) faces in the direction of the mobile station being connected is set as an selectable antenna pattern.

  If the base station apparatus 1 determines that RSSI measurement is not performed for all selectable antenna patterns, the base station apparatus 1 switches the switch 12 based on the control of the switch control unit 15 in step S16 to Change to a selectable antenna pattern that is not being received. On the other hand, if the base station apparatus 1 determines that RSSI measurement results have been obtained by receiving Message 3 for all selectable antenna patterns, the process proceeds to step S17.

  According to the base station apparatus 1 that executes the second antenna pattern determination process, in addition to the effect achieved by the first antenna pattern determination process, the quality of communication with the connected mobile station is not degraded. The direction of arrival of the signal from the mobile station can be estimated.

  In the first and second antenna pattern determination processes, the received signal strength is measured by RSSI measurement as an example of the reception quality measured by the quality measurement unit. However, the quality of the received signal may be measured by measuring SINR (Signal-to Interference and Noise Power Ratio) instead of RSSI measurement or together with RSSI measurement.

  In the first and second antenna pattern determination processes described above, the base station apparatus 1 receives the antenna 10 so as to receive Message 3 with an antenna pattern having one directivity every time Message 3 is transmitted from the mobile station once. Switched. However, the base station apparatus 1 may switch the antenna 10 so as to receive Message 3 sequentially using a plurality of antenna patterns during reception of Message 3 once. Hereinafter, it demonstrates in detail using a flowchart.

  FIG. 7 is a flowchart for explaining a third antenna pattern determination process executed by the base station apparatus 1 in the present embodiment.

  This third antenna pattern determination process is a process corresponding to the first antenna pattern determination process of FIG.

  Steps S21 to S23 are substantially the same processes as the reception steps S1 to NACK transmission step S3 in the first antenna pattern determination process, and thus description thereof is omitted here.

  In step S24, the base station apparatus 1 measures the RSSI of Message3 from the received signal in the RSSI measurement unit 32. The RSSI measuring unit 32 measures the RSSI for a certain time shorter than the signal length of Message3. The RSSI measurement unit 32 stores the measurement result in the storage unit 33.

  Steps S25 and S26 are substantially the same processes as the measurement determination step S5 and the pattern change step S6 in the first antenna pattern determination process, and thus description thereof is omitted here.

  In step S27, the base station apparatus 1 determines whether or not Message 3 is being received. When it is determined that Message 3 is being received, the base station apparatus 1 proceeds to measurement result storage step S24, measures RSSI with the changed antenna pattern, and stores the measured RSSI in the storage unit 33. The base station apparatus 1 sequentially changes the antenna pattern by switching the switch 12 during reception of one Message 3 and measures RSSI using a plurality of antenna patterns. That is, the base station apparatus 1 repeats antenna pattern change and RSSI measurement as many times as possible while receiving Message 3 once.

  When the base station apparatus 1 determines that the message 3 is not being received in the reception determination step S27, that is, when it is determined that the transmission of one message 3 by the mobile station has been completed, the base station apparatus 1 proceeds to the NACK transmission step S23.

  Steps S28 to S30 are substantially the same as the pattern determination step S7 to the transmission step S9 of the first antenna pattern determination process, and thus the description thereof is omitted here.

  FIG. 8 is a flowchart for explaining the fourth antenna pattern determination process executed by the base station apparatus 1 in the present embodiment.

  The fourth antenna pattern determination process is a process corresponding to the second antenna pattern determination process of FIG. That is, in the fourth antenna pattern determination process, the base station apparatus 1 waits for an uplink signal from the mobile station using an antenna pattern that forms omnidirectionality or directivity, and is moving while connected to the base station apparatus 1. This process is suitable when a station exists.

  Step S31 to Step S33, Step S36, Step S38 to Step S40 are respectively reception step S1 to NACK transmission step S3, pattern change step S6, pattern determination step S7 to transmission step in the first antenna pattern determination process (FIG. 5). The process is almost the same as S9. Steps S34 and S37 are substantially the same as the measurement result storage step S24 and the reception determination step S27 in the third antenna pattern determination process (FIG. 7). Step S35 is substantially the same as the measurement determination step S15 in the second antenna pattern determination process (FIG. 6). For this reason, description of each process is abbreviate | omitted here.

  The base station apparatus 1 that performs the third and fourth antenna pattern determination processes estimates the direction of arrival with a small number of retransmissions by measuring RSSI using a plurality of antenna patterns during reception of one RACH Message 3. Can be done. As a result, the delay time until the establishment of the uplink with the mobile station can be reduced.

  In the first to fourth antenna pattern determination processes, the process of determining an antenna pattern using Message 3 of RACH has been described. However, the signal used to determine the antenna pattern is another signal that can be retransmitted from the base station apparatus 1 or communication quality information such as CQI (Channel Quality Indicator) notified from the mobile station. It may be used. For example, the base station apparatus 1 corrects the uplink arrival direction estimation accuracy or follows the movement of the mobile station by using SRS (Sounding Reference Symbol) transmitted from the mobile station during data communication. Is also possible.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Base station apparatus 10 Antenna 12 Switch 13 Transmission / reception system part 14 Reactance element 15 Switch control part 21 RF part 22 Demodulation part 23, 30 Rate conversion part 24 Decoding part 25 Error detection part 26 Reception data processing part 27 CRC judgment part 28 Transmission data Generation unit 29 Encoding unit 31 Modulation unit 32 RSSI measurement unit 33 Storage unit 34 Pattern determination unit

Claims (10)

Multiple antennas,
An antenna switching unit that switches the combination of the antennas to form a plurality of directional antenna patterns or omnidirectional antenna patterns directed in different directions;
A receiving unit for receiving a predetermined signal transmitted from a mobile station from the antenna;
A switching control unit for controlling the antenna switching unit and receiving the signal using the required directional antenna pattern;
A quality measuring unit that measures the reception quality of each of the signals received using each of the directional antenna patterns;
A base station apparatus comprising: a pattern determination unit that determines an antenna pattern that maximizes the reception quality based on a measurement result of the reception quality as an antenna pattern used for communication with the mobile station. . A transmission unit for transmitting a retransmission request signal for requesting retransmission of the signal to the mobile station or a delivery confirmation signal indicating that delivery of the signal has been confirmed;
The signal transmitted from the mobile station is a signal transmitted a plurality of times based on the retransmission request signal,
The switching control unit controls the antenna switching unit to receive the signal with one directional antenna pattern each time the signal is received from the mobile station.
2. The transmission unit transmits the retransmission request signal until reception of the signal using the required directional antenna pattern is completed, and transmits the delivery confirmation signal when reception of the signal is completed. Base station equipment. A transmission unit for transmitting a retransmission request signal for requesting retransmission of the signal to the mobile station or a delivery confirmation signal indicating that delivery of the signal has been confirmed;
The signal transmitted from the mobile station is a signal transmitted a plurality of times based on the retransmission request signal,
The switching control unit controls the antenna switching unit so that the signal is sequentially received by a plurality of the directional antenna patterns while the signal is received once from the mobile station,
2. The transmission unit transmits the retransmission request signal until reception of the signal using the required directional antenna pattern is completed, and transmits the delivery confirmation signal when reception of the signal is completed. Base station equipment. The base station apparatus according to claim 2 or 3, wherein the switching control unit controls the antenna switching unit so that the signal is received using all the directional antenna patterns. When there is another mobile station connected to the base station device, the switching control unit is configured to receive the signal with a directional antenna pattern having directivity including the direction of the mobile station. The base station apparatus of Claim 2 or 3 which controls. The base station apparatus according to claim 1, wherein the signal transmitted from the mobile station is Message 3 transmitted using a random access channel. The quality measurement unit measures the reception quality by measuring at least one of RSSI (Receive Signal Strength Indicator) or SINR (Signal-to-Interference and Noise power Ratio) of the signal. The base station apparatus according to the item. Switching a combination of a plurality of antennas to form a plurality of directional antenna patterns or omnidirectional antenna patterns directed in different directions;
Receiving a predetermined signal transmitted from a mobile station from the antenna;
Receiving the signal using the required directional antenna pattern;
Measuring each reception quality of the signal received using each directional antenna pattern;
And determining an antenna pattern that maximizes the reception quality as an antenna pattern used for communication with the mobile station based on a measurement result of the reception quality. Further comprising the step of transmitting a retransmission request signal for requesting retransmission of the signal to the mobile station or a delivery confirmation signal indicating that delivery of the signal has been confirmed,
The signal transmitted from the mobile station is a signal transmitted a plurality of times based on the retransmission request signal,
The step of forming the antenna pattern switches the antenna pattern so that the signal is received by one directional antenna pattern each time the signal is received from the mobile station.
9. The transmitting step transmits the retransmission request signal until reception of the signal using the required directional antenna pattern is completed, and transmits the delivery confirmation signal when reception of the signal is completed. The antenna control method described. Further comprising the step of transmitting a retransmission request signal for requesting retransmission of the signal to the mobile station or a delivery confirmation signal indicating that delivery of the signal has been confirmed,
The signal transmitted from the mobile station is a signal transmitted a plurality of times based on the retransmission request signal,
The step of forming the antenna pattern switches the antenna pattern so that the signal is sequentially received by a plurality of the directional antenna patterns while the signal is received once from the mobile station.
9. The transmitting step transmits the retransmission request signal until reception of the signal using the required directional antenna pattern is completed, and transmits the delivery confirmation signal when reception of the signal is completed. The antenna control method described.

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