JP2010177912A - Radio base station and communication control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio base station and a communication control method, which suitably estimate the level of a communication quality. <P>SOLUTION: The radio base station receives a CQI notification including: a SB-CQI as a CQI associated with a SB with the highest CQI among BPs for every BP; and a WB-CQI as an average of CQIs in a frequency band in a down direction. The radio base station interpolates a CQI of a missing SB with a lower one of an SB-CQI as a CQI of another SB included in the same BP with the missing SB, and the WB-CQI. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radio base station that assigns a channel to a radio terminal based on CQI fed back from the radio terminal, and a communication control method in the radio base station.

  In a wireless communication system using frequency division duplex (FDD), a wireless base station performs scheduling for assigning a frequency (channel) with good communication quality to a wireless terminal. At this time, the radio base station allocates a downlink channel to the radio terminal based on a downlink CQI (Channel Quality Indicator) fed back from the radio terminal, and further determines a modulation scheme and the like. .

  In LTE (Long Term Evolution) which is a 3.9G communication system, the frequency band of the system is divided into units called BP (Bandwidth Part), and BP is further divided into units called SB (Sub Band). The In the Periodic Feedback mode in LTE, in order to reduce the amount of feedback and efficiently use the uplink channel, the wireless terminal can only use the CQI of the SB for the SB having the highest CQI in one BP. SB-CQI) is fed back to the radio base station. The wireless terminal feeds back an average CQI (WB-CQI) in the frequency band of the system.

3GPP TS 36.213 V8.4.0 “Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Layer procedures (Release 8)”

  However, in such a radio communication system, the radio base station can acquire only SB-CQIs for some SBs among SBs in one BP. For this reason, when the SB-CQI between wireless terminals competes in the scheduler assignment determination process, there is a situation in which the wireless base station must assign a channel corresponding to an SB whose SB-CQI is unknown to a certain wireless terminal. Arise.

  In this case, when the SB-CQI for the SB in the downlink direction allocated to the wireless terminal is so low that communication is impossible, the communication in the downlink direction becomes difficult.

  In addition, the wireless terminal actually has a CQI that can select a high modulation scheme. However, since such a CQI is unknown at the wireless base station, it is necessary to select the lowest-ranking modulation scheme. I don't get it. For this reason, the transmission capacity of the entire system is impaired.

  Therefore, an object of the present invention is to provide a radio base station and a communication control method capable of appropriately estimating the communication quality level.

  In order to solve the above-described problems, the present invention has the following features. First, a first feature of the present invention is configured in a wireless communication system in which a downlink band is divided into a plurality of first frequency bands, and each of the first frequency bands is divided into a plurality of second frequency bands. A radio base station (radio base station 1) having the highest quality among the first quality level indicating the average communication quality in the downlink band and the communication quality of the plurality of second frequency bands in the first frequency band. A receiving unit (CQI information receiving unit 120) that receives a second quality level indicating communication quality from a wireless terminal, and a second frequency band other than the second frequency band corresponding to the second quality level in the first frequency band. An interpolation unit (missing CQI interpolation unit 140) that interpolates a third quality level indicating the communication quality of the frequency band, and the interpolation unit selects the lower one of the first quality level and the second quality level. The third quality And summarized in that selected as the bell.

  In such a radio base station, the receiving unit receives the average communication quality (first quality level) of the downlink band and the communication quality (second quality level) for the SB having the highest CQI in one BP, The lower one of the first quality level and the second quality level is selected as the communication quality (third quality level) in the second frequency band other than the second frequency band corresponding to the second quality level. If the second quality level is higher than the first quality level, the second quality level may be significantly higher than the third quality level. For this reason, the 3rd quality level can be appropriately estimated by making the 3rd quality level into the 1st quality level lower than the 2nd communication quality level. Also, the third quality level cannot exceed the second quality level. For this reason, when the second quality level is lower than the first quality level, the third quality level can be appropriately estimated by setting the third quality level to the second quality level.

  A second feature of the present invention relates to the first feature, and when the interpolation unit selects the second quality level as the third quality level, the third quality level is changed from the second quality level. The gist is to make it a low level.

  A third feature of the present invention relates to the first feature or the second feature, and based on the second quality level and the third quality level, a frequency band in a downlink direction is provided to the wireless terminal. The gist of the present invention is to include an allocation unit (scheduler 150) for allocating.

  A fourth feature of the present invention relates to any one of the first feature to the third feature, wherein the interpolating unit has an elapsed time after receiving the second quality level from the wireless terminal. Accordingly, the gist is to lower the second quality level.

  A fifth feature of the present invention is that the wireless communication system is configured in a wireless communication system in which a downlink band is divided into a plurality of first frequency bands, and each of the first frequency bands is divided into a plurality of second frequency bands. A communication control method in a base station, wherein the radio base station includes a first quality level indicating an average communication quality in the downlink band, and a communication quality of the plurality of second frequency bands in the first frequency band, Receiving a second quality level indicating the highest communication quality from the radio terminal; and the radio base station in the first frequency band is a second frequency band other than the second frequency band corresponding to the second quality level. Interpolating a third quality level indicating the communication quality of the frequency band, and the interpolating step includes selecting a lower one of the first quality level and the second quality level as the third quality level. It is selected as the gist of the.

  ADVANTAGE OF THE INVENTION According to this invention, the radio | wireless base station and communication control method which can estimate the level of communication quality appropriately can be provided.

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 an example of the frequency band of the downlink direction which concerns on embodiment of this invention. It is a schematic block diagram of the radio base station which concerns on embodiment of this invention. It is a functional block block diagram of the control part in the radio base station which concerns on embodiment of this invention, a receiving part, and a transmission part. It is a functional block diagram of a missing CQI interpolation unit according to an embodiment of the present invention. It is a figure which shows an example of WB-CQI and SB-CQI which the wireless base station which concerns on embodiment of this invention received. It is a figure which shows an example of the interpolation by the missing CQI interpolation part which concerns on embodiment of this invention. It is a schematic block diagram of the radio | wireless terminal which concerns on embodiment of this invention. It is a functional block block diagram of the radio | wireless terminal which concerns on embodiment of this invention. It is a flowchart which shows the operation | movement of the wireless base station which concerns 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 operation of the radio base station, (3) the operation and effect, and (4) 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 First, regarding the configuration of the radio communication system according to the embodiment of the present invention, (1.1) overall schematic configuration of radio communication system, (1.2) configuration of radio base station, (1 .3) The configuration of the wireless terminals will be described in the order.

(1.1) Overall Schematic 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.

  As shown in FIG. 1, the radio communication system 10 is an LTE (Long Term Evolution) radio communication system that is a 3.9G communication system. The radio communication system 10 includes a radio base station 1, a radio terminal 2A, a radio terminal 2B, and a radio terminal 2C. In FIG. 1, radio terminals 2A to 2C are located in a cell 3 provided by the radio base station 1.

  As shown in FIG. 2, the downlink frequency band (downlink band) in the wireless communication system 10 is divided into units called BP (Bandwidth Part). BP is divided into units called SB (Sub Band), and SB is further divided into RBs (Resouce Blocks).

(1.2) Configuration of Radio Base Station Next, regarding the configuration of the radio base station 1, (1.2.1) schematic configuration of the radio base station, (1.2.2) detailed configuration of the radio base station. explain.

(1.2.1) Schematic Configuration of Radio Base Station FIG. 3 is a schematic configuration diagram of the radio base station 1. As illustrated in FIG. 3, the radio base station 1 includes a control unit 102, a storage unit 103, a wired communication unit 104, a reception unit 105, a transmission unit 106, and an antenna 107.

  The control unit 102 is configured by a CPU, for example, and controls various functions provided in the radio base station 1. The storage unit 103 is configured by a memory, for example, and stores various types of information used for control and the like in the radio base station 1. The wired communication unit 104 is connected to an access gateway or the like existing in the upper network via a router or the like (not shown).

  The receiving unit 105 receives wireless signals from the wireless terminals 2A to 2C via the antenna 107. The transmitting unit 106 transmits a radio signal to the radio terminals 2A to 2C via the antenna 107.

(1.2.2) Detailed Configuration of Radio Base Station Next, a detailed configuration of the radio base station 1, specifically, functional block configurations of the control unit 102, the reception unit 105, and the transmission unit 106 will be described. FIG. 4 is a functional block configuration diagram of the control unit 102, the reception unit 105, and the transmission unit 106. In FIG. 4, the control unit 102 includes a missing SB recognition unit 130, a missing CQI interpolation unit 140, and a scheduler 150. The receiving unit 105 includes a CQI information receiving unit 120, and the transmitting unit 106 includes a transmission signal generating unit 160.

  In the following description, it is assumed that the radio base station 1 communicates with the radio terminal 2A. However, the same applies when the radio base station 1 communicates with the radio terminal 2B and the radio terminal 2C.

  The CQI information receiving unit 120 receives the CQI notification transmitted from the wireless terminal 2A. The CQI notification includes, for each BP, a CQI (hereinafter referred to as SB-CQI) for an SB having the highest CQI (Channel Quality Indicator) in the BP and an SB ID (SB-ID) corresponding to the SB-CQI. Including. Also, the CQI notification includes an average of CQIs in the downlink frequency band (hereinafter, WB-CQI) in the wireless communication system 10. The CQI information receiving unit 120 outputs the CQI notification to the missing SB recognition unit 130.

  The missing SB recognition unit 130 determines whether there is an SB not notified of CQI based on the SB ID included in the CQI notification input from the CQI information receiving unit 120. When there is an SB for which CQI is not notified, the SB is recognized as a missing SB. Specifically, the missing SB recognition unit 130 recognizes an SB having an SB-ID other than the SB-ID corresponding to the SB-CQI included in the CQI notification as a missing SB.

  When there is a missing SB, the missing SB recognition unit 130 outputs a CQI notification to the missing CQI interpolation unit 140.

  The missing CQI interpolation unit 140 interpolates the CQI of the missing SB using the WB-CQI and SB-CQI included in the CQI notification input from the missing CQI interpolation unit 140.

  FIG. 5 is a functional block diagram of the missing CQI interpolation unit 140. The missing CQI interpolation unit 140 includes a CQI comparison unit 142 and a CQI determination unit 144.

  The CQI comparison unit 142 inputs the SB-CQI and WB-CQI for each BP from the missing SB recognition unit 130. Next, the CQI comparison unit 142 compares SB-CQI and WB-CQI corresponding to the BP for each BP. Furthermore, CQI comparison section 142 outputs the one showing the lower communication quality among SB-CQI and WB-CQI to CQI determination section 144.

  The CQI determination unit 144 sets the input WB-CQI or SB-CQI as the CQI of the missing SB in the corresponding BP. Further, when the CQI of the missing SB is set to SB-CQI, the CQI determination unit 144 lowers the CQI of the missing SB by a predetermined amount.

  Then, CQI determination section 144 outputs CQI notification and CQI of the determined missing SB to scheduler 150.

  FIG. 6 is a diagram illustrating an example of WB-CQI and SB-CQI received by the radio base station 1 from the radio terminal 2A. FIG. 7 is a diagram illustrating an example of the CQI interpolation of the missing SB by the missing CQI interpolation unit 140 in the case of FIG.

  In FIG. 6, the downlink frequency band in the wireless communication system 10 is divided into BP1, BP2, and BP3. Further, BP1 is divided into SB11, SB12 and SB13, BP2 is divided into SB21, SB22 and SB23, and BP3 is divided into SB31, SB32 and SB33.

  The radio base station 1 receives the CQI of SB12 in BP1, the CQI of SB21 in BP2, and the CQI of SB33 in BP3 as SB-CQI corresponding to each BP. At this time, the missing SB recognition unit 130 recognizes SB11, SB13, SB22, SB23, SB31, and SB32 corresponding to the CQI that has not been received as missing SBs.

  In the case of FIG. 6, in BP1, WB-CQI is lower than CQI of SB12 which is SB-CQI. Therefore, CQI comparison section 142 outputs WB-CQI for BP1 to CQI determination section 144. In BP2, the CQI of SB21 that is SB-CQI is lower than WB-CQI. Therefore, the CQI comparison unit 142 outputs the CQI of SB21 that is SB-CQI for BP1 to the CQI determination unit 144. In BP3, CQI of SB33 which is SB-CQI is lower than WB-CQI. Therefore, the CQI comparison unit 142 outputs the CQI of SB33, which is SB-CQI for BP1, to the CQI determination unit 144.

  The CQI determination unit 144 inputs WB-CQI for BP1. Further, the CQI determination unit 144 sets the SB11 and SB13 CQIs that are missing SBs for BP1 as WB-CQI (interpolation SB-CQI1 in FIG. 7).

  Further, the CQI determination unit 144 inputs the CQI of SB21 that is SB-CQI for BP2. Therefore, the CQI determination unit 144 sets the SB22 and 23 CQIs that are missing SBs for BP2 as SB-CQI that is the SB21 CQI (interpolated SB-CQI2 in FIG. 7).

  Also, the CQI determination unit 144 inputs the CQI of SB33 that is SB-CQI for BP3. Therefore, the CQI determining unit 144 sets the SB31 and 32 CQIs that are missing SBs for BP3 as SB-CQI that is the SB33 CQI (interpolated SB-CQI3 in FIG. 7).

  Further, the CQI determination unit 144 lowers the determined CQIs of the SB22 and SB23 by a predetermined amount (interpolation SB-CQI2-2 in FIG. 7). Similarly, the CQI determination unit 144 lowers the determined CQI of the SB 31 and SB 32 by a predetermined amount (interpolation SB-CQI 3 in FIG. 7).

  Then, the CQI determination unit 144 outputs the CQI notification and the determined CQIs of SB11, SB13, SB22, SB23, SB31, and SB32 to the scheduler 150.

  Returning to FIG. 4 again, functional block configurations of the control unit 102, the reception unit 105, and the transmission unit 106 will be described.

  The scheduler 150 allocates a channel to the radio terminal 2A using the CQI notification input from the CQI determination unit 144 and the determined CQI of the missing SB.

  The transmission signal generation unit 160 generates a transmission signal that notifies the channel information assigned by the scheduler 150 to the wireless terminal 2A. The transmission signal generation unit 160 transmits the generated transmission signal to the wireless terminal 2A.

(1.3) Configuration of Wireless Terminal Next, the configuration of the wireless terminal 2A will be described in the order of (1.3.1) Schematic configuration of the wireless terminal and (1.3.2) Detailed configuration of the wireless terminal.

(1.3.1) Schematic Configuration of Radio Terminal FIG. 8 is a schematic configuration diagram of the radio terminal 2A. The wireless terminal 2B and the wireless terminal 2C have the same configuration. As illustrated in FIG. 8, the wireless terminal 2A is, for example, a voice terminal, and includes an RF unit 201, a control unit 203, a microphone 205, a speaker 207, and an antenna 209.

  The RF unit 201 includes an RF circuit, a baseband circuit, and the like, performs modulation and demodulation, encoding, decoding, and the like, and transmits and receives radio signals via the antenna 209.

  The control unit 203 is configured by a CPU, for example, and controls various functions provided in the wireless terminal 2.

  The microphone 205 collects sound and outputs sound data based on the collected sound to the control unit 203. The speaker 207 outputs sound based on the sound data acquired from the control unit 203.

(1.3.2) Detailed Configuration of Wireless Terminal Next, a detailed configuration of the wireless terminal 2A, specifically, a functional block configuration of the control unit 203 will be described. FIG. 9 is a functional block configuration diagram of the control unit 203. In FIG. 9, the control unit 203 includes a CQI calculation unit 230 and an SB-CQI selection unit 232.

  The CQI calculation unit 230 calculates the CQI in each SB based on the radio signal received by the RF unit 201 via the antenna 209. In addition, CQI calculation section 230 calculates WB-CQI based on the received radio signal. The CQI calculation unit 230 outputs the CQI and WB-CQI of each SB to the SB-CQI selection unit 232.

  The SB-CQI selection unit 232 inputs from the CQI calculation unit 230. Furthermore, the SB-CQI selection unit 232 selects, for each BP, the highest CQI among SB CQIs in the BP as the SB-CQI. The SB-CQI selection unit 232 generates a CQI notification including the SB-CQI and the WB-CQI in each BP. The SB-CQI selection unit 232 outputs the generated CQI notification to the RF unit 201.

  The RF unit 201 transmits a CQI notification to the radio base station 1.

(2) Operation of Radio Base Station FIG. 10 is a flowchart showing the operation of the radio base station 1 in the radio communication system 10.

  In step S101, the CQI information receiving unit 120 of the radio base station 1 receives a CQI notification from the radio terminal 2A.

  In step S102, the missing SB recognition unit 130 of the radio base station 1 determines whether there is an SB with missing CQI (missing SB).

  When there is a missing SB (YES in step S102), in step S103, the CQI comparison unit 142 of the radio base station 1 determines whether SB-CQI is higher than WB-CQI.

  When WB-CQI is larger than SB-CQI (YES in step S103), in step S104, the CQI determination unit 144 of the radio base station 1 sets the SB included in the same BP as the missing SB as the CQI of the missing SB. Select the corresponding SB-CQI. In step S105, the CQI determination unit 144 lowers the CQI of the missing SB by a predetermined amount and proceeds to step S102.

  Thereafter, step S103 to step S105 are repeated until it is determined in step S102 that there is no SB lacking CQI. That is, the process is repeatedly executed according to the number of missing SBs.

  On the other hand, when WB-CQI is equal to or less than SB-CQI (NO in step S103), in step S107, CQI determination unit 144 of radio base station 1 selects WB-CQI as the CQI of the missing SB. Thereafter, the process proceeds to step S106.

  If there is no missing SB (NO in step S102), the process proceeds to step S106.

  In step S106, the scheduler 150 of the radio base station 1 performs scheduling based on the CQI of all SBs of the radio terminal 2A. Specifically, a channel determined based on the CQI of all SBs is allocated to the wireless terminal 2A.

(3) Operation / Effect As described above, according to the present embodiment, the missing CQI interpolation unit 140 compares the SB-CQI and the WB-CQI, and selects the lower one as the CQI of the missing SB. According to such a radio base station 1, the CQI of the missing SB is interpolated by the lower of the SB-CQI and the WB-CQI that are the CQIs of other SBs included in the same BP as the missing SB. It will be.

  If the SB-CQI is higher than the WB-CQI, the SB-CQI may be significantly higher than the CQI of the missing SB. For this reason, the radio base station 1 can appropriately estimate the CQI of the missing SB by setting the CQI of the missing SB to a WB-CQI lower than the SB-CQI.

  Further, the CQI of the missing SB cannot exceed the SB-CQI. Therefore, when the SB-CQI is lower than the WB-CQI, the radio base station 1 can appropriately estimate the CQI of the missing SB by setting the CQI of the missing SB as the SB-CQI. Further, when the CQI of the missing SB is set to SB-CQI, the radio base station 1 further estimates the CQI of the missing SB more appropriately by lowering the CQI of the missing SB by a predetermined amount. Can do.

  Also, according to the present embodiment, the radio base station 1 allocates a channel to a radio terminal using the interpolated missing SB CQI and CQI notification. For this reason, the radio base station 1 can appropriately perform scheduling even when the missing SB exists and the missing SB must be assigned to the wireless terminal.

(4) Other Embodiments In this embodiment, the CQI determination unit 144 measures an elapsed time since the CQI notification was received. Furthermore, the CQI determination unit 144 decreases the SB-CQI included in the CQI notification as the elapsed time is longer.

  As the elapsed time from the reception of the CQI notification becomes longer, the SB-CQI included in the CQI notification is more likely to deviate from the current SB-CQI. Specifically, the current SB-CQI is likely to be lower than the SB-CQI included in the CQI notification as the elapsed time from the reception of the CQI notification becomes longer.

  For this reason, the CQI determination unit 144 reduces the SB-CQI included in the CQI notification as the elapsed time from when the CQI is received, so that an appropriate divergence from the current SB-CQI is considered. SB-CQI can be set.

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

  DESCRIPTION OF SYMBOLS 1 ... Wireless base station, 2A-2C ... Wireless terminal, 3 ... Cell, 10 ... Wireless communication system, 102 ... Control part, 103 ... Memory | storage part, 104 ... Wired communication part, 105 ... Reception part, 106 ... Transmission part, 107 ... Antenna, 120 ... CQI information receiving unit, 130 ... Missing SB recognition unit, 140 ... Missing CQI interpolation unit, 142 ... CQI comparing unit, 144 ... CQI determining unit, 150 ... Scheduler, 160 ... Transmission signal generating unit, 201 ... RF , 203 ... Control unit, 205 ... Microphone, 207 ... Speaker, 209 ... Antenna, 230 ... CQI calculation unit, 232 ... CQI selection unit

Claims (5)

A wireless base station configured in a wireless communication system in which a downlink band is divided into a plurality of first frequency bands, and each of the first frequency bands is divided into a plurality of second frequency bands,
A first quality level indicating the average communication quality in the downlink band and a second quality indicating the highest communication quality among the communication qualities of the plurality of second frequency bands in the first frequency band for each first frequency band. A receiving unit for receiving a quality level from a wireless terminal;
An interpolation unit for interpolating a third quality level indicating communication quality in a second frequency band other than the second frequency band corresponding to the second quality level in the first frequency band;
The interpolation unit selects a lower one of the first quality level and the second quality level as the third quality level.   The radio base station according to claim 1, wherein, when the second quality level is selected as the third quality level, the interpolation unit sets the third quality level to a level lower than the second quality level.   3. The radio base station according to claim 1, further comprising: an assigning unit that assigns a downlink frequency band to the radio terminal based on the second quality level and the third quality level.   4. The radio base station according to claim 1, wherein the interpolating unit lowers the second quality level according to an elapsed time after receiving the second quality level from the radio terminal. 5. . A communication control method in a radio base station configured in a radio communication system in which a downlink band is divided into a plurality of first frequency bands, and each of the first frequency bands is divided into a plurality of second frequency bands. ,
The wireless base station has a first quality level indicating an average communication quality in the downlink band, and the highest communication quality of the plurality of second frequency bands in the first frequency band for each first frequency band. Receiving a second quality level indicative of communication quality from the wireless terminal;
The radio base station interpolating a third quality level indicating communication quality of a second frequency band other than the second frequency band corresponding to the second quality level in the first frequency band, and
The interpolating step selects the lower one of the first quality level and the second quality level as the third quality level.

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