JP5775706B2 - Radio base station and communication control method - Google Patents

Description

  The present invention relates to a radio base station that controls the radio terminal based on a reference signal from the radio terminal, and a communication control method in the radio base station.

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

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

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

  The following method is assumed as a method for calculating the antenna weight. That is, when the radio base station eNB receives a sounding reference signal (SRS) that is an uplink radio signal from the radio terminal UE, the radio base station eNB has the same frequency band as the frequency band of the SRS most recently received by the radio base station eNB. The downlink radio resource (downlink resource block) is allocated to the radio terminal UE that is the latest SRS transmission source. Further, the radio base station eNB calculates an antenna weight for the allocated downlink resource block. On the other hand, when the other radio base stations eNB in the vicinity receive the SRS, null steering is performed, and the antenna weight is calculated so that the null is directed toward the radio terminal UE that is the transmission source of the SRS.

  In this case, the radio terminal UE periodically transmits SRS according to the specification. However, when many radio terminals UE connected to the radio base station eNB transmit SRS, SRS overlaps (multiplexes) in the same frequency band at the same timing. For this reason, other radio base stations eNB in the vicinity cannot uniquely determine the source of SRS and cannot direct null.

  In view of the above problems, an object of the present invention is to provide a radio base station and a communication control method that enable appropriate null steering by neighboring radio base stations.

In order to solve the above-described problems, the present invention has the following features. The first feature of the present invention is to wirelessly communicate with a plurality of radio terminals (radio terminal UE2-1, radio terminal UE2-2, radio terminal UE2-3, radio terminal UE2-4) using time division duplex, Radio base station (eNB1-1) that controls the arrangement of transmission frequency bands for each of the plurality of radio terminals in the usable frequency band to transmit a reference signal (SRS) according to the bandwidth of the transmission frequency band The number of the plurality of wireless terminals that wirelessly communicate with the wireless base station and the wireless communication unit (wireless communication unit 106) that receives the reference signal transmitted from each of the plurality of wireless terminals at the same timing is A control unit (control unit 102) that selects a radio terminal that stops transmission of the reference signal based on an index indicating a state of radio communication by each of the plurality of radio terminals when there are more than the number of transmission frequency bands And summarized in that provided.

  When such a radio base station arranges the transmission frequency band of the reference signal in the usable frequency band, the radio base station performs the arrangement according to the bandwidth of the transmission frequency band of the reference signal in the radio terminal. Therefore, for example, at a predetermined timing, the radio base station can arrange the transmission frequency band of the wide reference signal and the transmission frequency band of the narrow reference signal at different positions in the usable frequency band. Such control prevents reference signals from overlapping in the same frequency band at the same timing. For this reason, other wireless base stations in the vicinity can uniquely determine the transmission source of the reference signal, and appropriate null steering is possible.

A second feature of the present invention is that the transmission frequency band includes a large frequency band and a small frequency band having a smaller bandwidth than the large frequency band, and the control unit includes the plurality of radio frequencies. Among the terminals, for the wireless terminal whose transmission power required for the reference signal is less than a predetermined value, the transmission frequency band corresponding to the large frequency band is set, and the transmission power required for the reference signal is greater than or equal to a predetermined value. The gist is to set the transmission frequency band corresponding to the small frequency band for a certain wireless terminal .

According to a third aspect of the present invention, the control unit stops the transmission of the reference signal for a number of wireless terminals that exceed the number of transmission frequency bands in order from the wireless terminal with the smallest index. The gist is to select as

A fourth feature of the present invention is that radio frequency communication with a plurality of radio terminals using time division duplex is performed, and an arrangement of transmission frequency bands for each of the plurality of radio terminals to transmit a reference signal in an available frequency band Is a communication control method in a radio base station that controls according to the bandwidth of the transmission frequency band, the step of receiving a reference signal transmitted from each of the plurality of radio terminals at the same timing, and the own radio base station A wireless terminal that stops transmission of the reference signal based on an index indicating a state of wireless communication by each of the plurality of wireless terminals when the number of the plurality of wireless terminals that wirelessly communicate with the wireless communication terminal is greater than the number of the transmission frequency bands And a step of selecting.

  According to the present invention, it is possible to perform appropriate null steering by surrounding radio base stations.

1 is an overall schematic configuration diagram of a wireless communication system according to an embodiment of the present invention. It is a figure which shows the format of a resource block based on embodiment of this invention. It is a figure which shows the format of the flame | frame based on embodiment of this invention. It is a figure which shows the structure of the frequency band which can be utilized in the radio | wireless communication between a radio base station and a radio | wireless terminal based on embodiment of this invention. 1 is a configuration diagram of a radio base station according to an embodiment of the present invention. It is a figure which shows the 1st example of arrangement | positioning of the radio | wireless terminal based on embodiment of this invention. It is a figure which shows the 1st example of the setting and arrangement | positioning of a SRS transmission frequency band based on embodiment of this invention. It is a figure which shows the 2nd example of arrangement | positioning of the radio | wireless terminal based on embodiment of this invention. It is a figure which shows the 2nd example of the setting and arrangement | positioning of a SRS transmission frequency band based on embodiment of this invention. It is a flowchart which shows the 1st operation | movement of the wireless base station based on embodiment of this invention. It is a flowchart which shows 2nd operation | movement of the wireless base station based on embodiment of this invention. It is a flowchart which shows the 3rd operation | movement of the wireless base station based on embodiment of this invention.

  Next, an embodiment of the present invention will be described with reference to the drawings. Specifically, (1) the configuration of the radio communication system, (2) the configuration of the radio base station, (3) the operation of the radio base station, (4) operations and effects, and (5) other embodiments will be described. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

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

  A wireless communication system 10 illustrated in FIG. 1 is a TDD-LTE wireless communication system. The radio communication system 10 includes a radio base station eNB1-1, a radio terminal UE2-1, a radio terminal UE2-2, a radio terminal UE2-3, and a radio terminal UE2-4.

  In FIG. 1, a radio base station eNB1-1 configures an E-UTRAN (Evolved-UMTS Terrestrial Radio Access Network). The radio terminals UE2-1 to UE2-4 exist in the cell 3-1, which is a communicable area provided by the radio base station eNB1-1.

  The radio terminals UE2-1 to UE2-4 are resource block allocation targets by the radio base station eNB1-1. In this case, on the basis of the radio base station eNB1-1, the radio terminals UE2-1 to UE2-4 are serving radio terminals. Hereinafter, the radio terminal to which resource blocks are allocated by the radio base station eNB1-1 is referred to as a serving radio terminal UE2 as appropriate.

  Time division duplex is adopted for radio communication between the radio base station eNB1-1 and radio terminals UE2-1 to UE2-4, and OFDMA (Orthogonal Frequency Division Multiplexing Access) is used for downlink radio communication. ), SC-FDMA (Single Carrier Frequency Division Multiple Access) is adopted for uplink wireless communication. Here, downlink means a direction from the radio base station eNB1-1 to the radio terminals UE2-1 to UE2-4. Uplink means a direction from the radio terminals UE2-1 to UE2-4 to the radio base station eNB1-1.

  The radio base station eNB1-1 assigns a resource block (RB: Resource Block) as a radio resource to the serving radio terminal UE2 in the cell 3-1.

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

  FIG. 2 is a diagram illustrating a format of a resource block. As shown in FIG. 2, the resource block is configured by one subframe having a time length of 1 [ms] in the time direction. The subframe includes time zones S1 to S14. Of these time zones S1 to S14, time zones S1 to S7 constitute the first half time slot (time slot 1), and time zones S8 to S14 consist of the second half time slot (time slot 2). ).

  As shown in FIG. 2, the resource block has a frequency width of 180 [kHz] in the frequency direction. The resource block is composed of 12 symbol carriers F1 to F12 having a frequency width of 15 [kHz].

  In the time direction, one frame is composed of a plurality of subframes. FIG. 3 is a diagram showing a frame format. The frame shown in FIG. 3 is composed of 10 subframes. The frame includes 10 subframes: a subframe of a downlink resource block, a subframe of both a downlink resource block and an uplink resource block (special subframe: SSF), a subframe of an uplink resource block, and a subframe of an uplink resource block , Downlink resource block subframe, downlink resource block subframe, special subframe, uplink resource block subframe, uplink resource block subframe, downlink resource block subframe.

  Further, in the frequency direction, the frequency band that can be used in radio communication between the radio base station eNB1-1 and the serving radio terminal UE2 has a band for a plurality of resource blocks. Also, the frequency band is divided into frequency bands that are multiples of 4 times the resource block. FIG. 4 is a diagram illustrating a configuration of a frequency band that can be used in radio communication between the radio base station eNB1-1 and the serving radio terminal UE2. As shown in FIG. 4, the frequency band that can be used in the radio communication between the radio base station eNB1-1 and the serving radio terminal UE2 has a band of 80 resource blocks. The frequency band is divided into a large frequency band 1 to a large frequency band 4 each having a band corresponding to 20 resource blocks. Further, the frequency band can be divided into frequency bands (small frequency band 1 to small frequency band 5) having bands for four resource blocks instead of any of the large frequency bands.

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

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

(2) Configuration of Radio Base Station FIG. 5 is a configuration diagram of the radio base station eNB1-1. As illustrated in FIG. 5, the radio base station eNB1-1 is an adaptive array radio base station that applies antenna weights to a plurality of antennas, and includes a control unit 102, a storage unit 103, an I / F unit 104, and radio communication. Unit 106, modulation / demodulation unit 107, antenna 108A, antenna 108B, antenna 108C, and antenna 108D.

  The control unit 102 is configured by a CPU, for example, and controls various functions provided in the radio base station eNB1-1. The control unit 102 controls the serving radio terminal UE2 based on the sounding reference signal (SRS) transmitted from the serving radio terminal UE2.

  The memory | storage part 103 is comprised by memory, for example, and memorize | stores the various information used for control etc. in the radio base station eNB1-1.

  The I / F unit 104 can communicate with other radio base stations eNB via the X1 interface. Further, the I / F unit 104 can communicate with an EPC (Evolved Packet Core) (not shown), specifically, an MME (Mobility Management Entity) / S-GW (Serving Gateway) via the S1 interface.

  The radio communication unit 106 receives an uplink radio signal transmitted from the serving radio terminal UE2-1 via the antenna 108A to the antenna 108D. Further, the radio communication unit 106 converts (down-converts) the received uplink radio signal into a baseband signal and outputs the baseband signal to the modulation / demodulation unit 107.

  The modulation / demodulation unit 107 demodulates and decodes the input baseband signal. Thereby, data included in the uplink radio signal transmitted by the radio terminal UE2-1 is obtained. Data is output to the control unit 102.

  Also, the modulation / demodulation unit 107 encodes and modulates data from the control unit 102 to obtain a baseband signal. The radio communication unit 106 converts (up-converts) the baseband signal into a downlink radio signal. Further, the modulation / demodulation unit 107 transmits a downlink radio signal via the antennas 108A to 108D.

  Next, specific processing of the control unit 102 will be described. The control unit 102 performs the following first process and second process.

(First process)
The control part 102 discriminate | determines the electric power required when the serving radio | wireless terminal UE2 which exists in the cell 3-1 transmits SRS with a predetermined | prescribed frequency bandwidth. The power required when the serving radio terminal UE2 transmits the SRS with a predetermined frequency bandwidth (the SRS transmission required power) is a power at which the radio base station eNB1-1 can normally receive the SRS without a signal error or the like. is there. In general, the power required for SRS transmission increases as the distance from the radio base station eNB1-1 increases.

  The control unit 102 sets a division (frequency band division) in the usable frequency band according to the SRS transmission required power of each serving radio terminal UE2. Specifically, the control unit 102 divides the usable frequency band into a plurality of large frequency bands when there is a serving radio terminal UE2 whose SRS transmission required power is less than a predetermined value. Further, when there is a serving radio terminal UE2 whose SRS transmission required power is greater than or equal to a predetermined value, the control unit 102 divides it into a plurality of small frequency bands instead of any of the large frequency bands.

  Next, the control unit 102 arranges the SRS transmission frequency band in the usable frequency band. Specifically, the control unit 102 arranges SRS transmission frequency bands having a large frequency band bandwidth and a small frequency band bandwidth according to the frequency band section set as the usable frequency band.

  Next, the control unit 102 sets an SRS transmission frequency band for each serving radio terminal UE2. Specifically, the control unit 102 sets the SRS transmission frequency band corresponding to the large frequency band for the serving radio terminal UE2 whose SRS transmission required power is less than a predetermined value. Moreover, the control part 102 sets the SRS transmission frequency band corresponding to a small frequency band with respect to the serving radio | wireless terminal UE2 whose SRS transmission required power is more than predetermined value.

  Next, the control unit 102 transmits SRS transmission frequency band information to the serving radio terminal UE2 via the modulation / demodulation unit 107, the radio communication unit 106, and the antennas 108A to 108D. The SRS transmission frequency band information includes, for example, numerical values of the upper limit frequency and the lower limit frequency of the corresponding SRS transmission frequency band. When the serving radio terminal UE2 receives the SRS transmission frequency band information, the serving radio terminal UE2 transmits the SRS using the frequency band specified by the SRS transmission frequency band information at the timing of the special subframe.

  At this time, the serving radio terminal UE2 transmits the SRS while switching the SRS transmission frequency band at each timing of the special subframe by the frequency hopping method.

  In the present embodiment, the switching order in the frequency hopping scheme is common to each serving radio terminal UE2. In the present embodiment, switching is performed in the order of large frequency band 1, large frequency band 3, large frequency band 2, and large frequency band 4 shown in FIG. It becomes. However, the SRS transmission frequency band of each serving radio terminal UE2 at the same timing is different. Accordingly, by setting the SRS transmission frequency band at the timing of the predetermined special subframe to be different for each serving radio terminal UE2, the SRS transmission frequency band in each special subframe after the predetermined special subframe is This is different for each radio terminal UE2.

  Also in the small frequency band, the frequency hopping method is adopted as in the large frequency band. Further, the five small frequency bands are treated as one large frequency band, and the frequency hopping method is adopted together with the other large frequency bands.

  Thereafter, the control unit 102 allocates a downlink resource block in the same frequency band as the most recently received SRS frequency band to the serving radio terminal UE2 that is the latest SRS transmission source. Furthermore, the control unit 102 calculates an antenna weight for the allocated downlink resource block.

  On the other hand, other radio base stations eNB in the vicinity not shown perform null steering when receiving the SRS, and for the radio terminal UE2 that is the source of the SRS (serving radio terminal UE2 for the radio base station eNB1-1) Thus, the antenna weight is calculated so that the null faces.

(Second process)
The second process is performed under a predetermined condition after the SRS transmission frequency band is set for the serving radio terminal UE2 by the first process. The second processing is performed independently for each of the large frequency band and the small frequency band.

  The control unit 102 determines whether or not the number of serving radio terminals UE2 is greater than the number of SRS transmission frequency bands. When processing the large frequency band, the control unit 102 determines that the number of serving radio terminals UE2 that have set the SRS transmission frequency band corresponding to the large frequency band is the SRS transmission frequency band having the large frequency band bandwidth. It is determined whether the number is greater than When performing processing for the small frequency band, the control unit 102 determines that the number of serving radio terminals UE2 that have set the SRS transmission frequency band corresponding to the small frequency band is the SRS transmission frequency band having the small frequency band bandwidth. It is determined whether the number is greater than

  When the number of serving radio terminals UE2 is larger than the number of SRS transmission frequency bands, the control unit 102 compares PF (Propotional Fair) values of the serving radio terminals UE2. The PF value is an index indicating the state of radio communication by the serving radio terminal UE2. When processing is performed for the large frequency band, the control unit 102 compares the PF values of the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the large frequency band. When performing processing for the small frequency band, the control unit 102 compares the PF values of the serving radio terminal UE2 that sets the SRS transmission frequency band corresponding to the small frequency band.

  Next, the control unit 102 selects the number of service radio terminals UE2 that exceed the number of SRS transmission frequency bands in order from the serving radio terminal UE2 having the smallest PF value, and stops transmission of SRS to the selected service radio terminal UE2. RRC Connection Reconfiguration which is a message including information to be instructed (transmission stop instruction information) is transmitted. Here, it is assumed that there is one serving radio terminal UE2 that exceeds the number of SRS transmission frequency bands. In the case of performing processing for the large frequency band, the control unit 102 issues a transmission stop instruction to the serving radio terminal UE2 having the smallest PF value among the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the large frequency band. Send RRC Connection Reconfiguration including information. When performing processing for the small frequency band, the control unit 102 sends a transmission stop instruction to the serving radio terminal UE2 having the smallest PF value among the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the small frequency band. Send RRC Connection Reconfiguration including information.

  When the serving radio terminal UE2 receives the RRC Connection Reconfiguration including the transmission stop instruction information, the serving radio terminal UE2 stops transmitting the SRS.

  Next, the control unit 102 responds from the serving radio terminal UE2 that is the transmission destination of the RRC Connection Reconfiguration including the transmission stop instruction information in each of the processing for the large frequency band and the processing for the small frequency band. It is determined whether or not RRC Connection Reconfiguration Complete, which is a message including transmission stop instruction response information (transmission stop instruction response information), has been received.

  When the RRC Connection Reconfiguration Complete is received, the control unit 102, among the serving radio terminals UE2 other than the serving radio terminal UE2 that is the transmission source of the RRC Connection Reconfiguration Complete, serves at least the serving radio terminal (other servings) that starts transmission of the SRS. Radio terminal) RRC Connection Reconfiguration, which is a message including SRS transmission frequency band information, is transmitted to UE2 via modulation / demodulation unit 107, radio communication unit 106, and antennas 108A to 108D. When performing processing for the large frequency band, the control unit 102 is the serving radio terminal UE2 that sets the SRS transmission frequency band corresponding to the large frequency band, and is the serving serving as the transmission source of RRC Connection Reconfiguration Complete RRC Connection Reconfiguration that is a message including SRS transmission frequency band information is transmitted to at least a serving wireless terminal (other serving wireless terminal) UE2 that starts transmission of SRS among serving wireless terminals UE2 other than wireless terminal UE2. To do. When performing processing for the small frequency band, the control unit 102 serves as the serving radio terminal UE2 that sets the SRS transmission frequency band corresponding to the small frequency band, and is the source of RRC Connection Reconfiguration Complete. RRC Connection Reconfiguration that is a message including SRS transmission frequency band information is transmitted to at least a serving wireless terminal (other serving wireless terminal) UE2 that starts transmission of SRS among serving wireless terminals UE2 other than wireless terminal UE2. To do.

  Thereafter, the control unit 102 compares the PF values of the serving radio terminals UE2. When processing is performed for the large frequency band, the control unit 102 compares the PF values of the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the large frequency band. When performing processing for the small frequency band, the control unit 102 compares the PF values of the serving radio terminal UE2 that sets the SRS transmission frequency band corresponding to the small frequency band.

  Next, the control unit 102 has the service radio terminal UE2 that stops transmission of the SRS selected at the time of the previous PF value comparison in each of the processing for the large frequency band and the processing for the small frequency band. Then, it is determined whether or not the selected service radio terminal UE2 has changed between the service radio terminal UE2 that stops transmission of the SRS selected at the time of the comparison of the PF values this time. Here, it is determined whether or not the serving radio terminal UE2 having the smallest PF value has changed between the previous PF value comparison and the current PF value comparison.

  When the serving radio terminal UE2 with the smallest PF value switches to the serving radio terminal UE2 that is transmitting the SRS, the transmission stop instruction information to the serving radio terminal UE2 with the new PF value (the PF value at the time of this comparison) is the smallest RRC Connection Reconfiguration which is a message including When performing processing for the large frequency band, the control unit 102, among the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the large frequency band, the SRS having the smallest PF value at the time of this comparison. RRC Connection Reconfiguration including the transmission stop instruction information is transmitted to the serving radio terminal UE2 that is transmitting. In the case of performing processing for the small frequency band, the control unit 102, among the serving radio terminals UE2 that set the SRS transmission frequency band corresponding to the small frequency band, the SRS that has the smallest PF value at the time of this comparison. RRC Connection Reconfiguration including the transmission stop instruction information is transmitted to the serving radio terminal UE2 that is transmitting.

  Next, the control unit 102 instructs the serving radio terminal UE2 having the smallest PF value (PF value at the previous comparison) that has stopped transmitting SRS to resume SRS transmission (transmission resumption instruction information). RRC Connection Reconfiguration which is a message including) is transmitted. The transmission resumption instruction information includes, for example, numerical values of the upper limit frequency and the lower limit frequency of the corresponding SRS transmission frequency band.

  When receiving the transmission resumption instruction information, the serving radio terminal UE2 resumes the transmission of the SRS using the frequency band specified by the transmission resumption instruction information at the timing of the special subframe.

  Next, the control unit 102 responds from the serving radio terminal UE2 that is the transmission destination of the RRC Connection Reconfiguration including the transmission stop instruction information in each of the processing for the large frequency band and the processing for the small frequency band. In response to the RRC Connection Reconfiguration Complete message including the transmission stop instruction response information, and the response from the serving radio terminal UE2 that is the transmission destination of the RRC Connection Reconfiguration including the transmission resumption instruction information. It is determined whether or not RRC Connection Reconfiguration Complete, which is a message including transmission resumption instruction response information, has been received. When the control unit 102 receives RRC Connection Reconfiguration Complete including transmission stop instruction response information and RRC Connection Reconfiguration Complete including transmission resumption instruction response information, the control unit 102 ends the series of processes.

  Thereafter, as in the first process, the control unit 102 allocates a downlink resource block in the same frequency band as the latest received SRS frequency band to the serving radio terminal UE2 that is the latest SRS transmission source. . Furthermore, the control unit 102 calculates an antenna weight for the allocated downlink resource block.

  On the other hand, other radio base stations eNB in the vicinity not shown perform null steering when receiving the SRS, and for the radio terminal UE2 that is the source of the SRS (serving radio terminal UE2 for the radio base station eNB1-1) Thus, the antenna weight is calculated so that the null faces.

  Hereinafter, an example of the second process will be described. As shown in FIG. 6, in a situation where the serving radio terminals UE2-1 to UE2-4 already exist in the cell 3-1, the serving radio terminals UE2-5 are newly added to the cell 3-1. Consider the case of entering.

  Here, it is assumed that the serving radio terminals UE2-1 to UE2-5 all have the SRS transmission power less than a predetermined value, and the transmittable frequency band is divided into four large frequency bands. .

  In this case, as shown in FIG. 7, initially, the serving radio terminals UE2-1 to UE2-4 transmit SRSs of transmission frequencies corresponding to different large frequency bands at the timing of the special subframe 201. ing. Thereafter, when the serving radio terminal 2-5 enters the cell 3-1, the number of serving radio terminals UE2 is one more than the number of SRS transmission frequency bands. For this reason, the control unit 102 provides the serving radio terminal UE2 having the lowest PF value among the serving radio terminals UE2-1 to UE2-5 (here, the serving radio terminals UE2-4). RRC Connection Reconfiguration including transmission stop instruction information is transmitted. Thereafter, at the timings of the special subframe 202 and the special subframe 203, the serving radio terminals UE2-1 to UE2-4 transmit SRS while switching the SRS transmission frequency band by the frequency hopping method.

  Thereafter, when receiving RRC Connection Reconfiguration Complete including transmission stop instruction response information from the serving radio terminals UE2-4, the control unit 102 transmits SRS transmission frequency band information to the serving radio terminals UE2-5. Thereafter, at the timing of the special subframe 204, the serving radio terminals UE2-5 start transmitting SRS, and the serving radio terminals UE2-4 stop transmitting SRS.

  Further, when the serving radio terminal UE2 having the lowest PF value is replaced with one of the serving radio terminals UE2 that is transmitting SRS (here, the SRS is transmitted from the serving radio terminals UE2-4 that have stopped transmitting SRS). The control unit 102 transmits the RRC connection reconfiguration including the transmission resumption instruction information to the serving radio terminals UE2-4 and the serving radio terminal UE2). -3, RRC Connection Reconfiguration including transmission stop instruction information is transmitted. Thereafter, at the timings of the special subframe 205 and the special subframe 206, the serving radio terminals UE2-1 to UE2-3 and the serving radio terminals UE2-5 switch the SRS transmission frequency band while switching the SRS transmission frequency band according to the frequency hopping method. Send.

  Thereafter, the control unit 102 receives RRC Connection Reconfiguration Complete including transmission resumption instruction response information from the serving radio terminals UE2-4, and RRC Connection Reconfiguration including transmission stop instruction response information from the serving radio terminals UE2-3. Receive Complete. Thereafter, at the timing of the special subframe 207, the serving radio terminals UE2-4 resume transmission of SRS, and the serving radio terminals UE2-3 stop transmitting SRS.

  Further, as shown in FIG. 8, in a situation where the serving radio terminals UE2-1 to UE2-4 already exist in the cell 3-1, the serving radio terminal UE2- is newly added to the cell 3-1. 5 and the serving radio terminal UE2-6 enter.

  Here, in the serving radio terminals UE2-1 to UE2-3 and the serving radio terminals UE2-6, the SRS transmission required power is less than a predetermined value, and the serving radio terminals UE2-4 and the serving radio terminals UE2-5 are Suppose that the required power for SRS transmission is equal to or greater than a predetermined value, and the transmittable frequency band is divided into four large frequency bands and five small frequency bands.

  In this case, as shown in FIG. 9, initially, at the timing of the special subframe 201, the serving radio terminals UE2-1 to UE2-3 transmit SRSs of transmission frequencies corresponding to different large frequency bands. The serving radio terminals UE2-4 are transmitting SRS having a transmission frequency corresponding to the small frequency band. Thereafter, when the serving radio terminal 2-5 and the serving radio terminal UE2-6 enter the cell 3-1, the number of serving radio terminals UE2 whose SRS transmission required power is less than a predetermined value is the SRS transmission corresponding to the large frequency band. One more than the number of frequency bands. For this reason, the control unit 102 serves as the serving radio terminal UE2 having the lowest PF value among the serving radio terminals UE2-1 to UE2-3 and the serving radio terminals UE2-6 (here, the serving radio terminals UE2-3). RRC Connection Reconfiguration including transmission stop instruction information is transmitted. On the other hand, the number of serving radio terminals whose required power for SRS transmission is equal to or greater than a predetermined value is equal to or less than the number of SRS transmission frequencies corresponding to the small frequency band. For this reason, the control part 102 transmits SRS transmission frequency band information with respect to serving radio | wireless terminal UE2-5.

  At the timing of the special subframe 202 and the special subframe 203, the serving radio terminal UE 2-1, the serving radio terminal UE 2-2, and the serving radio terminal UE 2-3 use an SRS transmission frequency band corresponding to a large frequency band by a frequency hopping method. SRS is transmitted while switching. In addition, at the timing of the special subframes 202 to 207, the serving radio terminals UE2-4 whose SRS transmission required power is a predetermined value or more switch the SRS while switching the SRS transmission frequency band corresponding to the small frequency band by the frequency hopping method. Send. Furthermore, at the timing of the special subframe 203, the serving radio terminal UE2-5 whose SRS transmission required power is a predetermined value or more starts transmission of SRS, and at the timing of the special subframes 204 to 207, the SRS transmission required power is The serving radio terminals UE2-6 that are less than the predetermined value transmit SRS while switching the SRS transmission frequency band corresponding to the large frequency band by the frequency hopping method.

  Thereafter, when receiving RRC Connection Reconfiguration Complete including transmission stop instruction response information from the serving radio terminals UE2-3, the control unit 102 transmits SRS transmission frequency band information to the serving radio terminals UE2-6. Thereafter, at the timing of the special subframe 204, the serving radio terminals UE2-6 start transmitting SRS, and the serving radio terminals UE2-3 stop transmitting SRS.

  Further, when the serving radio terminal UE2 having the lowest PF value is replaced with one of the serving radio terminals UE2 that is transmitting SRS (here, the SRS is transmitted from the serving radio terminals UE2-3 that have stopped transmitting SRS). The control unit 102 transmits the RRC Connection Reconfiguration including the transmission resumption instruction information to the serving radio terminal UE2-3, and the serving radio terminal UE2). -2, RRC Connection Reconfiguration including transmission stop instruction information is transmitted.

  Thereafter, the control unit 102 receives RRC Connection Reconfiguration Complete including transmission resumption instruction response information from the serving radio terminals UE2-3, and RRC Connection Reconfiguration including transmission stop instruction response information from the serving radio terminals UE2-2. Receive Complete. Thereafter, at the timing of the special subframe 207, the serving radio terminals UE2-3 resume transmission of SRS, and the serving radio terminals UE2-2 stop transmitting SRS.

(3) Operation of Radio Base Station FIGS. 10 to 12 are flowcharts showing the operation of the radio base station eNB1-1. FIG. 10 corresponds to the first process described above, and FIGS. 11 and 12 correspond to the second process described above.

  In step S101 of FIG. 10, the control unit 102 determines the power required when the serving radio terminal UE2 existing in the cell 3-1 transmits SRS with a predetermined frequency bandwidth (SRS transmission required power).

  In step S102, the control unit 102 sets a section (frequency band section) in the usable frequency band according to the SRS transmission required power of each serving radio terminal UE2.

  In step S103, the control unit 102 arranges the SRS transmission frequency band in the usable frequency band.

  In step S104, the control unit 102 arranges SRS transmission frequency bands having a large frequency band bandwidth and a small frequency band bandwidth according to the frequency band section set in the usable frequency band.

  In step S105, the control unit 102 sets an SRS transmission frequency band for each serving radio terminal UE2.

  In step S201 of FIG. 11, the control unit 102 determines whether or not the number of serving radio terminals UE2 is greater than the number of SRS transmission frequency bands.

  If the number of serving radio terminals UE2 is greater than the number of SRS transmission frequency bands, in step S202, the control unit 102 compares the PF values of the serving radio terminals UE2.

  In step S203, the control unit 102 selects the number of service radio terminals UE2 that exceeds the number of SRS transmission frequency bands in order from the serving radio terminal UE2 having the smallest PF value, and stops transmission of SRS to the selected service radio terminal UE2. RRC Connection Reconfiguration which is a message including information (transmission stop instruction information) instructing is transmitted. Here, as a result of the determination, it is assumed that the number of serving radio terminals UE2 is one more than the number of SRS transmission frequency bands, and information (transmission) instructing the serving radio terminal UE2 having the smallest PF value to stop SRS transmission. Assume that RRC Connection Reconfiguration which is a message including stop instruction information) is transmitted.

  In step S204, the control unit 102 includes transmission stop instruction response information (transmission stop instruction response information) that is a response from the serving radio terminal UE2 that is the transmission destination of the RRC connection reconfiguration including the transmission stop instruction information. It is determined whether or not RRC Connection Reconfiguration Complete is received.

  When RRC Connection Reconfiguration Complete is received, in step S205, the control unit 102 serves as a serving radio terminal that starts transmission of at least SRS among the serving radio terminals UE2 other than the serving radio terminal UE2 that is the transmission source of RRC Connection Reconfiguration Complete. (Other serving radio terminal) RRC Connection Reconfiguration which is a message including SRS transmission frequency band information is transmitted to UE2.

  In step S211 of FIG. 12, the control unit 102 compares the PF values of the serving radio terminals UE2.

  In step S212, the control unit 102 stops the transmission of the SRS selected at the previous PF value comparison and the service wireless terminal UE2 that stops the SRS transmission selected at the current PF value comparison. Then, it is determined whether or not the selected service radio terminal UE2 has changed, and here, whether or not the serving radio terminal UE2 having the smallest PF value has been changed.

  When the serving radio terminal UE2 with the smallest PF value switches to one of the serving radio terminals UE2 that is transmitting the SRS, in step S213, the control unit 102 is newly transmitting the SRS that stops the SRS transmission. RRC Connection Reconfiguration, which is a message including transmission stop instruction information, is transmitted to the serving radio terminal UE2 having the smallest new PF value (PF value at the time of this comparison).

  In step S214, the control unit 102 resumes SRS transmission, and instructs the serving radio terminal UE2 having the smallest original PF value (PF value at the previous comparison) to resume SRS transmission (transmission resume instruction information). RRC Connection Reconfiguration which is a message including) is transmitted.

  In step S215, the control unit 102 is an RRC Connection Reconfiguration Complete message that includes a transmission stop instruction response information that is a response from the serving radio terminal UE2 that is a transmission destination of the RRC Connection Reconfiguration including the transmission stop instruction information. RRC Connection Reconfiguration Complete, which is a message including transmission resumption instruction response information, which is a response from the serving radio terminal UE2 that is a transmission destination of RRC Connection Reconfiguration including transmission resumption instruction information. Is received. When receiving RRC Connection Reconfiguration Complete including transmission stop instruction response information and RRC Connection Reconfiguration Complete including transmission resumption instruction response information, the control unit 102 ends a series of operations.

(4) Operation / Effect In this embodiment, the radio base station eNB1-1 has more serving radio terminals UE2 in the cell 3-1 than the number of SRS transmission frequency bands set in the transmittable frequency band. In this case, an RRC Connection Reconfiguration including information (transmission stop instruction information) for instructing to stop SRS transmission is transmitted to the serving radio terminal UE2 that has a small PF value and is considered to have low SRS transmission priority. To do.

  Therefore, the number of serving radio terminals UE2 that transmit SRS is less than or equal to the number of SRS transmission frequency bands set in the transmittable frequency band, and SRS may overlap in the same frequency band at the same timing. Is prevented. For this reason, other radio base stations eNB in the vicinity can uniquely determine the transmission source of the SRS, and appropriate null steering is possible.

  In addition, after transmitting the transmission stop instruction information, the radio base station eNB1-1 has a PF value smaller than the serving radio terminal (first serving radio terminal) UE2 that is the transmission destination of the transmission stop instruction information, and the SRS When there is a serving radio terminal (second serving radio terminal) UE2 that is considered to have a low transmission priority, information for instructing the first serving radio terminal to resume SRS transmission (transmission resume instruction information) Send RRC Connection Reconfiguration including.

  Therefore, the radio base station eNB1-1 can appropriately select the serving radio terminal UE2 that should stop SRS transmission according to the change in the PF value, in other words, according to the change in the communication state.

  The radio base station eNB1-1 also includes an RRC including response information (transmission stop instruction response information) indicating that the transmission stop instruction information has been received from the serving radio terminal UE2 that is the transmission destination of the transmission stop instruction information. Send Connection Reconfiguration.

  Therefore, the radio base station eNB1-1 can recognize that the serving radio terminal UE2 has reliably received the transmission stop instruction information. For this reason, the radio base station eNB1-1 transmits SRS transmission frequency band information to the serving radio terminal UE2 other than the transmission destination of the transmission stop instruction response information after receiving the transmission stop instruction response information. It is reliably prevented that SRSs overlap in the same frequency band at the same timing.

  Further, the radio base station eNB1-1 arranges the large frequency band and the small frequency band in the usable frequency band according to the SRS transmission required power associated with the bandwidth of the SRS transmission frequency band in the serving radio terminal UE2. Do.

  Therefore, the radio base station eNB1-1 sets the SRS transmission frequency band corresponding to the large frequency band and the SRS transmission frequency band corresponding to the small frequency band at different positions in the usable frequency band at a predetermined timing. Can be arranged. Such control prevents SRSs from overlapping in the same frequency band at the same timing. For this reason, other wireless base stations in the vicinity can uniquely determine the transmission source of the SRS, and appropriate null steering is possible.

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

  In the embodiment described above, the control unit 102 divides the transmittable frequency band into a large frequency band and a small frequency band. However, the control unit 102 may divide the transmittable frequency band into frequency bands having three or more types of bandwidths.

  For example, the control unit 102 includes a serving radio terminal UE2 whose SRS transmission required power is greater than or equal to a first predetermined value, and a serving radio terminal UE2 whose SRS transmission necessary power is less than a first predetermined value and greater than or equal to a second predetermined value. When there is a serving radio terminal UE2 whose SRS transmission required power is less than the second predetermined value, the usable frequency band is divided into a large frequency band, a medium frequency band, and a small frequency band.

  Further, the control unit 102 arranges the transmission frequency band of the SRS having the bandwidth of the large frequency band, the bandwidth of the medium frequency band, and the bandwidth of the small frequency band according to the frequency band division set as the usable frequency band. To do.

  Next, the control part 102 sets the SRS transmission frequency band corresponding to a large frequency band with respect to the serving radio | wireless terminal UE2 whose SRS transmission required power is less than 2nd predetermined value. The control unit 102 sets the SRS transmission frequency band corresponding to the medium frequency band for the serving radio terminal UE2 whose SRS transmission required power is less than the first predetermined value and greater than or equal to the second predetermined value. The control unit 102 sets the SRS transmission frequency band corresponding to the small frequency band for the serving radio terminal UE2 whose SRS transmission required power is greater than or equal to the first predetermined value.

  In the embodiment described above, since the number of serving radio terminals UE2 that exceeds the number of SRS transmission frequency bands is one, the control unit 102 transmits the SRS to the serving radio terminal UE2 having the lowest PF value. Selected as serving radio terminal UE2 to be stopped. However, when the number of serving radio terminals UE2 exceeds the number of SRS transmission frequency bands is more than one, the control unit 102 causes the surplus serving radio terminals UE2 to stop the SRS transmission. You may select as UE2.

  For example, when the number of serving radio terminals UE2 is three more than the number of SRS transmission frequency bands, the control unit 102 causes the three serving radio terminals UE2 having lower PF values to serve as the serving radio terminal UE2 that should stop SRS transmission. Choose as. Furthermore, the control part 102 transmits RRC Connection Reconfiguration including transmission stop instruction information with respect to three selected serving radio | wireless terminals UE2.

  After that, when any one of the serving radio terminals UE having the lower three PF values is changed, the control unit 102 newly provides the serving radio terminal UE 2 having the lower three PF values. Then, the RRC Connection Reconfiguration including the transmission stop instruction information is transmitted, and the RRC Connection Reconfiguration including the transmission resumption instruction information is transmitted to the serving wireless terminal UE2 whose PF value is not the lower three.

  In the above-described embodiment, the control unit 102 selects the serving radio terminal UE2 that should stop SRS transmission based on the PF value. However, the control unit 102 may select the serving radio terminal UE2 having a low index as the serving radio terminal UE2 that should stop the transmission of the SRS, based on another index indicating the communication state of the serving radio terminal UE2. Moreover, the control part 102 may select each serving radio | wireless terminal UE2 as a serving radio | wireless terminal UE2 which should stop transmission of SRS sequentially by a round robin system.

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

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

  eNB1-1 ... radio base station, UE2-1, UE2-2, UE2-3, UE2-4, UE2-5, UE2-6 ... radio terminal, 3-1 ... cell, 10 ... radio communication system, 102 ... control , 103 ... Storage unit, 104 ... I / F unit, 106 ... Wireless communication unit, 107 ... Modulation / demodulation unit, 108A, 108B, 108C, 108D ... Antenna

Claims (4)

Time division duplex using signal communicating a plurality of radio terminals and the radio, the arrangement of the transmission frequency band for transmitting the plurality of wireless terminals reference signals respectively in the usable frequency band, the bandwidth of the transmission frequency band A radio base station controlled according to
A wireless communication unit that receives reference signals transmitted at the same timing from each of the plurality of wireless terminals;
When the number of the plurality of wireless terminals wirelessly communicating with the own wireless base station is greater than the number of the transmission frequency bands, the reference signal is transmitted based on an index indicating a state of wireless communication by each of the plurality of wireless terminals. A radio base station comprising a control unit that selects a radio terminal to be stopped. The transmission frequency band includes a large frequency band and a small frequency band having a smaller bandwidth than the large frequency band,
The control unit sets the transmission frequency band corresponding to the large frequency band for the wireless terminal whose required transmission power of the reference signal is less than a predetermined value among the plurality of wireless terminals, and the reference signal The radio base station according to claim 1, wherein the transmission frequency band corresponding to the small frequency band is set for a radio terminal having a required transmission power of at least a predetermined value.   The said control part selects the radio | wireless terminal of the number exceeding the number of the said transmission frequency bands in an order from the radio | wireless terminal with the said minimum index as the said radio | wireless terminal which stops transmission of the said reference signal. Radio base station. Time division duplex using signal communicating a plurality of radio terminals and the radio, the arrangement of the transmission frequency band for transmitting the plurality of wireless terminals reference signals respectively in the usable frequency band, the bandwidth of the transmission frequency band A communication control method in a radio base station that is controlled according to
Receiving a reference signal transmitted from each of the plurality of wireless terminals at the same timing;
When the number of the plurality of wireless terminals wirelessly communicating with the own wireless base station is greater than the number of the transmission frequency bands, the reference signal is transmitted based on an index indicating a state of wireless communication by each of the plurality of wireless terminals. Selecting a wireless terminal to be stopped;
A communication control method comprising:

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