JP2012114865A - Wireless base station and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To determine an appropriate modulation scheme without degrading throughput.SOLUTION: An eNB1-1 adopts frequency hopping which allocates a resource block to a UE2-1 according to frequency switching of an SRS from the UE2-1. When allocating a first downlink resource block to the UE2-1, an MCS of the first resource block is determined based on an SINR acquired for a second downlink resource block that has the same frequency band as that of the first downlink resource block and that was allocated to the UE2-1 in the past.

Description

  The present invention relates to a radio base station that allocates radio resources to a radio terminal according to switching of a frequency of 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) currently standardized, in wireless communication between a wireless base station (eNB) and a wireless terminal (UE), The eNB allocates a resource block (RB) that is a radio resource to the UE (see, for example, Non-Patent Document 1).

  As a method for assigning radio resources to radio terminals in a radio communication system, there is a method called frequency hopping that switches the frequency of radio resources assigned to radio terminals as needed. For example, frequency hopping can be employed in a wireless communication system such as a next generation PHS (eXtended Global Platform: XGP).

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

  In the frequency hopping in the above-described XGP radio communication system, the radio base station sets a modulation scheme (for example, BPSK) that is resistant to interference in order to prevent data corruption for newly allocated radio resources. For this reason, although it is possible to suppress the occurrence of retransmission processing, there is a problem that throughput is reduced. For this reason, it is not appropriate to employ frequency hopping as it is in the XGP wireless communication system as it is, particularly in an LTE wireless communication system that requires high throughput.

  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 can determine an appropriate modulation scheme without reducing the throughput.

  In order to solve the above-described problems, the present invention has the following features. A feature of the present invention is that a radio base station (eNB1-1) allocates a radio resource (RB) to the radio terminal according to switching of the frequency of a reference signal from the radio terminals (UE2-1, UE2-2). And a determination unit (MCS determination unit 116) that determines a modulation scheme (MCS: Modulation and Coding Scheme) in the radio resource, wherein the determination unit includes the latest first radio resource to be allocated to the radio terminal. Determining a modulation scheme for the first radio resource based on quality information (CQI, SINR) acquired for the second radio resource allocated to the radio terminal and having a frequency band different from the frequency band Is the gist.

  Such a radio base station employs frequency hopping in which radio resources are allocated to the radio terminal in response to switching of the frequency of the reference signal from the radio terminal, and the first radio resource is assigned to the radio terminal. When allocating, the modulation scheme in the first radio resource has a frequency band different from the frequency band of the first radio resource and is based on the quality information acquired for the second radio resource allocated to the radio terminal To decide. Therefore, the radio base station can use the quality information of the second radio resource in the past to determine the modulation scheme in the first radio resource, and can determine an appropriate modulation scheme without reducing the throughput. Can do.

  A feature of the present invention is that the determining unit is based on quality information acquired at a timing at which a time position in a reception cycle period of the reference signal is the same as the latest first radio resource assigned to the radio terminal, The gist is to determine a modulation scheme in the first radio resource.

  A feature of the present invention is that the determination unit determines a modulation scheme for the first radio resource based on the latest quality information among a plurality of quality information acquired in the past for the second radio resource. This is the gist.

  A feature of the present invention is that the determination unit determines a modulation scheme in the first radio resource based on an average value of quality values indicated by a plurality of quality information acquired in the past for the second radio resource. The gist is to decide.

  A feature of the present invention is that the determination unit increases the weighting coefficient as the elapsed time from acquisition of the quality value indicated by the plurality of quality information acquired in the past for the second radio resource is shorter. The gist is to determine a modulation scheme for the first radio resource based on the weighted average value.

  A feature of the present invention is a communication control method in a radio base station that allocates radio resources to the radio terminal in response to switching of the frequency of a reference signal from the radio terminal, and determines a modulation scheme in the radio resource The step of determining includes acquiring a second radio resource having a frequency band different from a frequency band of a latest first radio resource allocated to the radio terminal and allocated to the radio terminal in the past. The gist of the present invention is to determine a modulation scheme in the first radio resource based on the quality information.

  According to the present invention, it is possible to determine an appropriate modulation scheme without reducing the throughput.

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 of the radio | wireless resource which can be utilized in the radio | wireless communication between eNB and UE based on embodiment of this invention. It is a block diagram of eNB based on embodiment of this invention. It is a figure which shows the example of a response | compatibility with the frequency band of SRS, and allocation downlink RB based on embodiment of this invention. It is a figure which shows SINR shown by the CQI information which UE notifies with respect to eNB based on embodiment of this invention. It is a flowchart which shows 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, the configuration of the radio communication system, the configuration of the radio base station, the operation of the radio base station, the operation and effect, and 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 (eNB) 1-1 and a radio terminal (UE) 2-1.

  The UE 2-1 is a resource block allocation target by the eNB 1-1. In this case, if eNB1-1 is used as a reference, UE2-1 is a serving radio terminal.

  The radio communication between the eNB 1-1 and the UE 2-1 employs time division duplex, OFDMA (Orthogonal Frequency Division Multiplexing Access) for downlink radio communication, and SC-FDMA for uplink radio communication. (Single Carrier Frequency Division Multiple Access) is adopted. Downlink means the direction from eNB1-1 to UE2-1. Uplink means the direction from UE2-1 to eNB1-1.

  The eNB 1-1 assigns a resource block (RB: Resource Block) as a radio resource to the UE 2-1 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. Among these time zones S1 to S14, the symbols S1 to S7 constitute the first half time slot (time slot 1), and the symbols S8 to S14 constitute 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. 3A is composed of 10 subframes. The frame includes 10 subframes: a subframe of a downlink resource block, a subframe of both downlink resource blocks and uplink resource blocks (front special subframe: SSF) 300, a subframe of uplink resource blocks, and an uplink resource block , Sub-frame of downlink resource block, sub-frame of downlink resource block, rear special sub-frame 301, sub-frame of uplink resource block, sub-frame of uplink resource block, sub-frame of downlink resource block It is.

  In the special subframe, in the subframe, the first half time slot is used for downlink radio communication with the guard time in between, and the second half time slot is used for uplink radio communication. As shown in FIG. 3B, the special subframe includes an SRS symbol 1 and an SRS symbol 2 corresponding to the SRS transmission time zone at the end thereof.

  Further, in the frequency direction, all frequency bands of radio resources that can be used in radio communication between the eNB 1-1 and the UE 2-1, in other words, frequency bands that can be allocated to the UE 2-1 (allocated frequency bands). ) Has a bandwidth corresponding to the number of resource blocks.

  FIG. 4 is a diagram illustrating a configuration of a frequency band that can be used in wireless communication between the eNB 1-1 and the UE 2-1. The total frequency band that can be used in the radio communication between the eNB 1-1 and the UE 2-1 is a band corresponding to 100 resource blocks. Here, as shown in FIG. 4, the eNB 1-1 and the UE 2-1 Assume that 96 resource block bands are used as frequency bands that can be used in wireless communication with each other. Further, the frequency band is divided into frequency bands 1 to 4 having a band of 24 resource blocks.

  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 eNB FIG. 5 is a configuration diagram of the eNB 1-1. As illustrated in FIG. 5, the eNB 1-1 includes a control unit 102, a storage unit 103, an I / F unit 104, a wireless communication unit 106, a modulation / demodulation unit 107, and an antenna 108.

  The control part 102 is comprised by CPU, for example, and controls the various functions which eNB1-1 comprises. The control unit 102 includes a resource block (RB) allocation unit 114 and an MCS (Modulation and Coding Scheme) determination unit 116. The memory | storage part 103 is comprised by memory, for example, and memorize | stores the various information used for control etc. in eNB1-1.

  The I / F unit 104 can communicate with another eNB (not shown) via the X2 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 UE 2-1 via the antenna 108. 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 UE 2-1 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 radio communication unit 106 transmits a downlink radio signal via the antenna 108.

  The control unit 102 sets a frequency band (SRS transmission frequency band) used when the UE 2-1 transmits a sounding reference signal (SRS) at the timing of the special subframe with respect to the UE 2-1. Here, SRS is an uplink radio signal in a radio frequency band.

  In the present embodiment, the SRS transmission frequency band is switched regularly and alternately from frequency band 1 to frequency band 4 shown in FIG. When the control unit 102 sets the SRS transmission frequency band when the UE 2-1 transmits the SRS at the timing of the special subframe in the predetermined frame, the control unit 102 is the last downlink resource of the frame two frames before the predetermined frame. At the block timing, an RRC Connection Reconfiguration message including information on the set SRS transmission frequency band is transmitted to UE 2-1. The SRS transmission frequency band information includes parameters corresponding to the bandwidths of the frequency band 1 and the frequency band 2, parameters corresponding to the bandwidths of the frequency band 3 and the frequency band 4, the information of the SRS symbol 1, or the information of the SRS symbol 2. It consists of information and is set in SoundingRS-UL-Config which is an information element of the RRC Connection Reconfiguration message.

  The UE 2-1 receives an RRC Connection Reconfiguration message including information on the SRS transmission frequency band. Further, UE 2-1 has parameters corresponding to the bandwidths of frequency band 1 and frequency band 2 in the RRC Connection Reconfiguration message, parameters corresponding to the bandwidths of frequency band 3 and frequency band 4, and information on SRS symbol 1. Alternatively, information of SRS symbol 2 is extracted. Further, the UE 2-1 performs the SRSs of the frequency band 1 and the frequency band 2 at the timing of the extracted SRS symbol 1 or SRS symbol 2 in the special subframe on the front side in the frame two frames after the received timing frame. In the rear special subframe, transmission (SRS hopping transmission) is performed to transmit the SRSs of the frequency band 3 and the frequency band 4 at the timing of the extracted SRS symbol 1 or SRS symbol 2.

  The RB allocation unit 114 in the control unit 102 of the eNB 1-1 receives the SRS via the antenna 108, the radio communication unit 106, and the modulation / demodulation unit 107.

  Further, the RB allocation unit 114 determines whether there is data (downlink data) to be transmitted to the UE 2-1. When downlink data exists, the RB allocation unit 114 allocates downlink resource blocks to the UE 2-1. Here, the RB allocation unit 114 allocates a downlink resource block to the UE 2-1 in accordance with switching of the SRS frequency band by SRS hopping transmission in the UE 2-1.

  Specifically, as shown in FIG. 6, the RB allocating unit 114 has the latest received SRS frequency band and includes the latest SRS reception timing from the special subframe to the next special subframe. Is set as an allocatable area (UE allocatable area) for UE 2-1. The UE allocatable area includes subframes of two downlink resource blocks.

  Next, the RB allocating unit 114 allocates a sub-frame of a downlink resource block in any time zone among the sub-frames of two downlink resource blocks included in the UE allocatable area to the UE 2-1.

  Specifically, when the latest SRS reception timing is the timing of SRS symbol 1, RB allocation section 114, among the subframes of two downlink resource blocks included in the UE allocatable area, The time zone of the subframe of the resource block is selected as the time zone of the downlink resource block to be allocated. In addition, when the latest SRS reception timing is the timing of SRS symbol 2, RB allocation section 114 is the downstream downlink resource block of the two downlink resource blocks included in the UE allocatable area. The sub-frame time zone is selected as the sub-frame time zone of the downlink resource block to be allocated.

  Further, the RB allocation unit 114 generates a downlink RB allocation value that can uniquely identify the frequency band and time band of the subframe of the selected downlink resource block. The downlink RB allocation value is obtained by processing in the medium access control (MAC) layer. The downlink RB allocation value includes a resource block number that is information for uniquely identifying a time frame and a frequency band of a subframe of the downlink resource block allocated to the UE 2-1.

  The RB allocation unit 114 transmits information on the downlink RB allocation value to the UE 2-1 via the modulation / demodulation unit 107, the radio communication unit 106, and the antenna 108.

  The MCS determination unit 116 selects an MCS for transmitting downlink data using the subframe of the downlink resource block allocated to the UE 2-1. Here, the UE 2-1 transmits CQI (Channel Quality Indicator) information corresponding to the frequency band 1 to the frequency band 4 for each subframe of the allocated downlink resource block to the eNB 1-1. When receiving the CQI information, the MCS determination unit 116 acquires SINR (Signal to Interference and Noise power Ratio) corresponding to the CQI information.

  FIG. 7 is a diagram illustrating SINR indicated by the CQI information notified from the UE 2-1 to the eNB 1-1. FIG. 7 is an example in which subframes of two downlink resource blocks included in the UE allocatable area are allocated to UE 2-1.

  A time zone 1 to a time zone 5 shown in FIG. 7 are periods of an SRS reception cycle, in other words, a period of 5 [ms] that is an allocation cycle of downlink radio resources for the UE 2-1.

  In time zone 1, UE 2-1 is assigned downlink resource blocks in frequency band 1 and frequency band 2. In this case, UE 2-1 transmits CQI information corresponding to frequency bands 1 to 4 for each subframe of the allocated downlink resource block among the four subframes other than the special subframe in time zone 1. To do. SINRs corresponding to the frequency band 1 and the frequency band 2 are values indicated by 403 to 404.

  In time zone 2, UE 2-1 is assigned downlink resource blocks in frequency band 3 and frequency band 4. In this case, the UE 2-1 transmits CQI information corresponding to the frequency bands 1 to 4 for each subframe of the allocated downlink resource block among the four subframes other than the special subframe in the time zone 2. To do. SINRs corresponding to the frequency band 1 and the frequency band 2 have values indicated by 413 to 414.

  In time zone 3, as in time zone 1, UE 2-1 is assigned downlink resource blocks in frequency band 1 and frequency band 2. In this case, UE 2-1 transmits CQI information corresponding to frequency bands 1 to 4 for each subframe of the allocated downlink resource block among the four subframes other than the special subframe in time zone 1. To do. The SINRs corresponding to the frequency band 1 and the frequency band 2 are values indicated by 408 to 409.

  In the time zone 4, as in the time zone 2, the UE 2-1 is assigned the frequency band 3 and the downlink resource block of the frequency band 4. In this case, the UE 2-1 transmits CQI information corresponding to the frequency bands 1 to 4 for each subframe of the allocated downlink resource block among the four subframes other than the special subframe in the time zone 2. To do. SINRs corresponding to the frequency band 1 and the frequency band 2 have values indicated by 418 to 419.

  As is clear from FIG. 7, the two SINRs in each time zone decrease as the elapsed time from the allocation of the resource block to the UE 2-1 in the previous time zone increases.

  Hereinafter, in such a situation, the eNB 1-1 is a first process to a fourth process that are MCS determination processes in the downlink resource blocks of the frequency band 1 and the frequency band 2 allocated to the UE 2-1 in the time band 5. The process will be described.

(First process)
The MCS determination unit 116 has the frequency band 3 and 4 different from the frequency band 1 and the frequency band 2 allocated in the time band 5 in the past, in other words, the downlink resource blocks of the frequency band 3 and the frequency band 4 for the UE 2-1. The latest time zone 4 is selected from the time zone 2 and the time zone 4 which are time zones to which the downlink resource block is allocated. Next, the MCS determination unit 116 acquires the time position in the time zone 4 of the two SINRs in the time zone 4 at the same timing as the downlink resource blocks in the frequency band 1 and the frequency band 2 assigned in the time zone 5. The SINR 418 that is the selected SINR is selected as the SINR used for the determination of the MCS.

  Next, the MCS determination unit 116 determines the MCSs in the downlink resource blocks of the frequency band 1 and the frequency band 2 to be allocated in the time band 5 based on the selected SINR 418. Here, the MCS determination unit 116 determines the MCS so that the higher the SINR 418, the greater the throughput.

(Second process)
The MCS determination unit 116 has the frequency band 3 and 4 different from the frequency band 1 and the frequency band 2 allocated in the time band 5 in the past, in other words, the downlink resource blocks of the frequency band 3 and the frequency band 4 for the UE 2-1. The latest time zone 4 is selected from the time zone 2 and the time zone 4 which are time zones to which the downlink resource block is allocated. Next, the MCS determination unit 116 selects the SINR 419 that is the latest SINR among the two SINRs in the time zone 4.

  Next, the MCS determination unit 116 determines the MCS in the downlink resource blocks of the frequency band 1 and the frequency band 2 to be allocated in the time band 5 based on the selected SINR 419. Here, the MCS determination unit 116 determines the MCS so that the higher the SINR 419, the greater the throughput.

(Third process)
The MCS determination unit 116 has the frequency band 3 and 4 different from the frequency band 1 and the frequency band 2 allocated in the time band 5 in the past, in other words, the downlink resource blocks of the frequency band 3 and the frequency band 4 for the UE 2-1. The latest time zone 4 is selected from the time zone 2 and the time zone 4 which are time zones to which the downlink resource block is allocated. Next, the MCS determination unit 116 calculates an average value of the two SINRs 418 to SI419 419 in the time zone 4.

  Next, the MCS determination unit 116 determines MCSs in the downlink resource blocks of the frequency band 1 and the frequency band 2 to be allocated in the time band 5 based on the calculated average value of SINR. Here, the MCS determination unit 116 determines the MCS such that the higher the SINR average value, the greater the throughput.

(Fourth process)
The MCS determination unit 116 has the frequency band 3 and 4 different from the frequency band 1 and the frequency band 2 allocated in the time band 5 in the past, in other words, the downlink resource blocks of the frequency band 3 and the frequency band 4 for the UE 2-1. The time zone 2 and the time zone 4 which are the time zones to which the downlink resource blocks are allocated are selected.

  Next, the MCS determination unit 116 acquires the time position in the time zone 4 of the two SINRs in the time zone 4 at the same timing as the downlink resource blocks in the frequency band 1 and the frequency band 2 assigned in the time zone 5. The SINR 418 that is the selected SINR is selected as the SINR used for the determination of the MCS. In addition, the MCS determination unit 116, of the two SINRs 413 to SINR 414 in the time zone 2, the time position in the time zone 3 is at the same timing as the downlink resource blocks in the frequency band 1 and the frequency band 2 assigned in the time zone 5. The SINR 413 that is the acquired SINR is selected as the SINR used for determining the MCS.

  Next, the MCS determination unit 116 determines the weighting coefficient for the selected SINR 418 and SINR 413 so that the weighting coefficient becomes larger as the elapsed time after receiving the CQI information corresponding to the SINR is shorter. Further, the MCS determination unit 116 calculates a weighted average value of the SINR 418 and the SINR 413 using the weighting coefficient. For example, when a value of 0.5 or more and less than 1 is used as the weighting coefficient γ for the SINR 418, the weighted average value of the SINR 418 and the SINR 413 is (SINR 418 value) × γ + (SINR 413 value) × (1-γ). . Note that γ may be a PF value that is a value indicating the priority of resource block allocation to the UE 2-1 in, for example, the PF (Propotional Fair) method.

  The MCS determination unit 116 outputs the MCS determined in any of the first to fourth processes described above to the modulation / demodulation unit 107. Modulation / demodulation section 107 modulates downlink data according to the determined MCS, and transmits the modulated downlink data to UE 2-1 via radio communication section 106 and antenna 108.

(3) Operation of eNB FIG. 8 is a flowchart showing the operation of eNB 1-1.

  In step S101, the eNB 1-1 determines whether there is data (downlink data) to be transmitted to the UE 2-1. When there is no downlink data, a series of operations is completed.

  On the other hand, when downlink data exists, in step S102, eNB1-1 allocates a downlink resource block with respect to UE2-1.

  In step S103, eNB1-1 selects SINR used for MCS determination. A specific selection method is as shown in the first to third processes described above.

  In step S104, the eNB 1-1 determines the MCS based on the selected SINR. A specific determination method is as shown in the first to fourth processes described above.

  In step S105, the eNB 1-1 modulates downlink data according to the determined MCS, and transmits the modulated downlink data to the UE 2-1.

(4) Action / Effect As described above, according to the present embodiment, the eNB 1-1 assigns a resource block to the UE 2-1 in response to switching of the frequency of the SRS from the UE 2-1. Adopting frequency hopping, when allocating the first downlink resource block to UE 2-1, it has a frequency band different from the frequency band of the first downlink resource block, and has been allocated to UE 2-1 in the past Based on the SINR acquired for the second downlink resource block, the MCS in the first resource block is determined.

  Therefore, the eNB 1-1 can use the past SINR corresponding to the frequency band of the second downlink radio resource for the determination of the MCS in the first resource block, and can appropriately perform without reducing the throughput. The MCS can be determined.

(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 above-described embodiment, the timing of the special subframe is the SRS transmission timing in the serving UE 2-1. However, the transmission timing of the SRS is not limited to this, and may be a timing agreed in advance between the eNB 1-1 and the serving UE2. However, it is preferable that the SRS transmission timing exists at least once within the time of one frame.

  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 ... radio terminal, 3-1 ... cell, 10 ... radio communication system, 102 ... control unit, 103 ... storage unit, 104 ... I / F unit, 106 ... radio communication unit, 107: Modulation / demodulation unit, 108: Antenna, 114 ... RB allocation unit, 116 ... MCS determination unit

Claims (6)

A radio base station that allocates radio resources to the radio terminal in response to switching of the frequency of a reference signal from the radio terminal,
A determination unit for determining a modulation scheme in the radio resource;
The determination unit has a frequency band different from the frequency band of the latest first radio resource to be allocated to the radio terminal, and based on the quality information acquired for the second radio resource allocated to the radio terminal, A radio base station that determines a modulation scheme for the first radio resource.   The determination unit is configured to determine the first radio resource based on quality information acquired at a timing at which a time position in a reception cycle period of the reference signal is the same as the latest first radio resource assigned to the radio terminal. The radio base station according to claim 1, wherein a modulation scheme is determined.   The said determination part determines the modulation system in a said 1st radio | wireless resource based on the newest quality information among several quality information acquired in the past about the said 2nd radio | wireless resource. Radio base station.   The determination unit determines a modulation scheme for the first radio resource based on an average value of quality values indicated by a plurality of quality information acquired in the past for the second radio resource. The radio base station described.   For the quality value indicated by the plurality of quality information acquired in the past for the second radio resource, the determination unit sets the weighted average value to a larger weighting coefficient as the elapsed time from acquisition is shorter. The radio base station according to claim 1, wherein a modulation scheme for the first radio resource is determined based on the base station. A communication control method in a radio base station that allocates radio resources to the radio terminal in response to switching of the frequency of a reference signal from the radio terminal,
Determining a modulation scheme in the radio resource;
The determining step has a frequency band different from the frequency band of the latest first radio resource to be allocated to the radio terminal and is based on quality information acquired for the second radio resource allocated to the radio terminal. A communication control method for determining a modulation scheme in the first radio resource.

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