JP5547016B2 - Base station and base station control method - Google Patents

Description

  The present invention relates to a base station, and more particularly to a base station corresponding to an OFDM system.

  Standards based on OFDM (Orthogonal Frequency-Division Multiplexing) systems such as LTE (Long Term Evolution) and UMB (Ultra Mobile Broadband) are known as wireless communication systems between base stations and communication terminals. ing. In the OFDM system, the frequency band used for wireless communication is divided into a plurality of subbands. When transmitting data to communication terminals under its control, the base station performs scheduling of radio resources such as which subband data is allocated to which communication terminal. The base station uses a CQI (Channel Quality Indicator) report received from the communication terminal in order to appropriately perform scheduling. The CQI report is a report in which a communication terminal transmits downlink radio quality to a base station. The base station can improve downlink throughput by scheduling transmission data to a communication terminal in a frequency band with good radio quality based on the received CQI report (for example, Non-Patent Documents 1 and 2). reference).

  There are various formats for the CQI report transmitted from the communication terminal to the base station. For example, the CQI report includes average radio quality for all frequency bands, average radio quality for each subband, and the like. In addition, the data size of the CQI report varies depending on the format of the CQI report.

  For example, when the CQI report includes only the average radio quality of all frequency bands, the data size of the CQI report is reduced, and consumption of radio resources in the uplink direction can be suppressed. In addition, although the amount of information processed by the base station is small, in this case, the base station cannot acquire the radio quality for each subband only by the average radio quality of all frequency bands. For this reason, the base station may not be able to allocate communication terminals to subbands with good radio quality and may not be able to perform scheduling with high frequency utilization efficiency.

  Further, for example, when the CQI report includes the average radio quality for each subband in addition to the average radio quality of all frequency bands, the data size of the CQI report becomes large and the consumption of radio resources in the uplink direction increases. Moreover, although the amount of information processed by the base station increases, in this case, the base station can acquire the average radio quality for each subband for all the subbands. For this reason, the base station can perform scheduling with high frequency utilization efficiency by assigning communication terminals to subbands with good radio quality.

3GPP TS36.300 “11.5 CQI reporting for scheduling” 3GPP TS36.213 “7.2 UE procedure for reporting channel quality indication (CQI), precoding matrix indicator (PMI) and rank indication (RI)”

  As described above, the consumption of uplink radio resources and the scheduling load of the base station vary depending on the format of the CQI report. However, in the conventional technology, not all communication terminals under the base station use the same format CQI report, and a specific method for dynamically changing the format of the CQI report according to the surrounding situation is considered. Was not.

  For example, when the number of communication terminals under the base station is small, the communication band has a margin, and the base station does not necessarily perform strict scheduling in order to satisfy the QoS (Quality of Service) requirement of each communication terminal. May be. However, in the conventional technique, once the CQI report is set by the initial setting or the like, even if the QoS request of each communication terminal cannot be satisfied, the format of the CQI report cannot be changed dynamically. there were.

  Accordingly, an object of the present invention made in view of such a point is to provide a base station that can change the format of a CQI report used by all communication terminals in response to a QoS request of a communication terminal under its control. .

In order to solve the above-described problems, the invention of the base station according to the first aspect is as follows:
A base station compatible with the OFDM system,
A receiving unit for receiving channel quality information and a QoS request from a communication terminal under its own station;
A scheduler for scheduling transmission data and subbands to each communication terminal based on the channel quality information and the QoS request;
A determination unit that determines a channel quality information format that satisfies a QoS request of a communication terminal under its own station based on the channel quality information and the QoS request;
A transmission unit that transmits a change instruction to the channel quality information format to a communication terminal under its own station,
It is characterized by providing.

The invention according to the second aspect is a base station according to the first aspect,
The scheduler, when the channel quality information includes an average radio quality of all frequency bands and an average radio quality of at least one subband,
Scheduling is performed according to the difference between the average quality of the entire frequency band and the average radio quality of the at least one subband.

  As described above, the solution of the present invention has been described as an apparatus. However, the present invention can be realized as a method, a program, and a storage medium storing the program, which are substantially equivalent thereto, and the scope of the present invention. It should be understood that these are also included.

For example, the invention of the control method of the base station according to the third aspect that implements the present invention as a method is as follows:
A base station control method corresponding to an OFDM system,
Receiving channel quality information and a QoS request from a communication terminal under its control;
Scheduling transmission data and subbands to each communication terminal based on the channel quality information and the QoS request;
Determining, based on the channel quality information and the QoS request, a channel quality information format that satisfies a QoS request of a communication terminal under its own station;
Transmitting a change instruction to the channel quality information format to a communication terminal under its own station;
It is characterized by including.

  According to the present invention, it is possible to change the format of the CQI report used by all communication terminals in accordance with the QoS request of the communication terminal under its own station.

FIG. 1 is a diagram illustrating a schematic configuration of a base station according to an embodiment of the present invention. FIG. 2 is an operation flowchart of the base station shown in FIG. FIG. 3 is a flowchart showing details of the CQI report determination process.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram illustrating a schematic configuration of a base station according to an embodiment of the present invention. The base station 1 includes a receiving unit 10 that receives a CQI report (channel quality information) and a QoS request from a communication terminal (not shown) under its control, a control unit 20 that controls functions of the entire base station 1, A transmission unit 30 for transmitting data to the communication terminal. The control unit 20 responds to the QoS request of the communication terminal under its own station, and the scheduler 21 that schedules transmission data and downlink subbands to each communication terminal based on the CQI report and the QoS request received from the communication terminal. A CQI report determination unit 22 (determination unit) that determines a CQI report format (channel quality information format).

Here, in the present embodiment, the following four CQI report formats are used between the base station and the communication terminal.
Type 1: Average All Bands The “all band average” format CQI report includes only the average radio quality (all band averages) of all frequency bands used for downlink communication.
Type 2: Average of all bands + average of best subbands The CQI report in the form of "average of all bands + average of best subbands" shows the subband (best subband) with the best radio quality in addition to the average radio quality of all frequency bands It includes an average radio quality (best subband average) and an identifier indicating the position of the best subband.
Type 3: Average of all bands + M subband average The CQI report in the form of "Average of all bands + M subband average" is the top M subbands (M subbands) with good radio quality in addition to the average radio quality of all frequency bands. The average radio quality (M subband average) and an identifier indicating the position of the M subbands are included.
Type 4: Average of all bands + average of all subbands The CQI report in the form of "average of all bands + average of all subbands" shows the average radio quality for all subbands in addition to the average radio quality of all frequency bands. Is included.

  FIG. 2 is an operation flowchart of the base station 1 shown in FIG. When receiving the CQI report and the QoS request from the communication terminal under its control, the receiving unit 10 supplies the CQI report and the QoS request to the scheduler 21 (Step S101). The QoS request may be a CQI target level.

  Based on the CQI report and the QoS request supplied from the receiver 10, the scheduler 21 performs scheduling of transmission data and downlink subbands so as to satisfy the QoS of each communication terminal (step S102). The scheduling by the scheduler 21 differs depending on the CQI report format. Hereinafter, the scheduling operation of the scheduler 21 for each type 1 to type 4 CQI report format will be described in detail.

(Type 1: Average of all bands)
When the CQI report from each communication terminal is in the “all-band average” format, the scheduler 21 performs scheduling assuming that the radio quality of each subband is the radio quality indicated by “all-band average”. However, depending on the subband, the radio quality may be lower than “average of all bands”, so the scheduler 21 assumes that the radio quality of each subband is lower than “average of all bands”, and the margin It is also possible to perform scheduling in consideration of the above. The scheduler 21 assigns an arbitrary subband to the communication terminal according to the amount of data to each communication terminal. Here, actually, the radio quality of each subband is different. For this reason, the scheduler 21 can average the throughput to each communication terminal by rotating the subbands allocated to each communication terminal in the entire frequency band. By assigning subbands by rotation, the throughput to each communication terminal can be averaged without performing TPC (Transmission Power Control) control. The scheduler 21 can further stabilize the throughput to each communication terminal by performing TPC control.

(Type 2: Average of all bands + Best subband average)
When the CQI report from each communication terminal is in the “all band average + best subband average” format, the scheduler 21 performs scheduling to assign each communication terminal to the “best subband” of each communication terminal in principle. When the best subbands of a plurality of communication terminals overlap, the scheduler 21 performs scheduling for allocating the best subband to communication terminals having a larger difference between the average of all bands and the average of the best subbands. This is because when the difference between the average of the entire band and the average of the best subband is large, the amount of resources required differs greatly when the transmission data is allocated to the best subband and when allocated to other subbands. It is. For subbands with good radio quality, an efficient modulation class can be used, so that a large amount of data can be allocated to few radio resources. On the other hand, since efficient modulation classes cannot be used for subbands with poor radio quality, the number of required radio resources increases even with the same data amount. That is, the scheduler 21 can improve the user capacity by preferentially allocating the best subband to the communication terminal having a large difference between the average of all bands and the average of the best subband. The scheduler 21 assigns communication terminals that are not assigned to the best subband to other subbands. In this case, the scheduler 21 can average the throughput to each communication terminal by rotating the subbands assigned to each communication terminal in the entire frequency band. The scheduler 21 can further stabilize the throughput to each communication terminal by performing TPC control.

(Type 3: Average of all bands + M subband average)
When the CQI report from each communication terminal is in the “average of all bands + M subband average” format, the scheduler 21 basically transmits each communication to any subband included in the “M subband” of each communication terminal. Scheduling to allocate terminals. When M subbands of a plurality of communication terminals overlap, the scheduler 21 performs scheduling for preferentially assigning M subbands to communication terminals having a larger difference between the average of all bands and the average of M subbands. . The scheduler 21 can improve the user capacity by preferentially allocating subbands included in the M subband to communication terminals having a large difference between the average of all bands and the average of M subbands. The scheduler 21 assigns communication terminals that have not been assigned to the M subband to other subbands. In this case, the scheduler 21 can average the throughput to each communication terminal by rotating the subbands assigned to each communication terminal in the entire frequency band. The scheduler 21 can further stabilize the throughput to each communication terminal by performing TPC control.

(Type 4: Average of all bands + average of all subbands)
When the CQI report from each communication terminal is in the “all band average + all subband average” format, the scheduler 21 can obtain the average radio quality for each subband for all the communication terminals. The scheduler 21 performs scheduling for preferentially assigning a subband having the maximum difference to a communication terminal having a larger maximum value of the difference between the average of all bands and the average radio quality of each subband. In the case of this CQI report, the processing load on the scheduler 21 increases, but it is possible to assign an appropriate subband to each communication terminal.

  After scheduling by the scheduler 21, the CQI report determination unit determines the CQI report format according to the QoS request of the communication terminal under its own station (step S103). FIG. 3 is a flowchart showing details of CQI report determination in step S103 of FIG.

  In the flowchart of FIG. 3, the CQI report determination unit 22 determines whether the QoS request received from each communication terminal can be satisfied with the CQI report in the “all-band average” format (step S <b> 201). For example, when the number of communication terminals is relatively small and each communication terminal can secure a subband necessary for transmitting desired data without competing with other communication terminals, the CQI report determination unit 22 , It is determined that the QoS request can be satisfied by the CQI report in the “average of all bands” format. When the QoS request can be satisfied with the CQI report in the “all-band average” format, the CQI report determination unit 22 sets the “all-band average” format as the CQI report format (step S202).

  When the QoS request cannot be satisfied by the CQI report in the “all band average” format, the CQI report determination unit 22 converts the QoS request received from each communication terminal into the CQI in the “all band average + best subband” format. It is determined whether the report can be satisfied (step S203). For example, even when the number of communication terminals has slightly increased, the CQI report determination unit 22 determines whether each communication terminal's best subband overlaps with the best subband of another communication terminal. Since it suffices to schedule data in the best subband, it is determined that the QoS request can be satisfied by the CQI report in the format of “average of all bands + best subband”. When the QoS request can be satisfied by the CQI report in the “average of all bands + best subband” format, the CQI report determination unit 22 sets the “average of all bands + best subband” format as the CQI report format (step S204). ).

  When the QoS request cannot be satisfied by the CQI report in the “average of all bands + best subband” format, the CQI report determination unit 22 displays the QoS request received from each communication terminal as “average of all bands + M subband”. It is determined whether it can be satisfied with the formatted CQI report (step S205). For example, even when the number of communication terminals has increased considerably, the CQI report determination unit 22 does not repeat the duplication between the M subbands of each communication terminal and the M subbands of other communication terminals. Since it is only necessary to schedule data in any one of the M subbands, it is determined that the QoS request can be satisfied with the CQI report in the “all band average + M subband” format. When the QoS request can be satisfied with the CQI report in the “all band average + M subband” format, the CQI report determination unit 22 sets the “all band average + M subband” format as the CQI report format (step S206).

  When the QoS request cannot be satisfied by the CQI report in the “all band average + M subband” format, the CQI report determination unit 22 sets the “all band average + all subband average” format as the CQI report format ( Step S208). In other words, when the number of communication terminals is considerably increased, a CQI report of the “average of all bands + all subbands” format is used.

  When the CQI report determined in step S104 is different from the current CQI report (Yes in step S104), the CQI report determination unit 22 automatically issues a change command to the CQI report format determined in step S104 from the transmission unit 30. It transmits to the communication terminal under the station (step S105). The communication terminal that has received the change command changes the CQI report format and transmits the radio quality information to the base station in the changed CQI report format.

  As described above, according to the present embodiment, the CQI report determination unit 22 determines the CQI report format that satisfies the QoS request of the number of communication terminals under its own station based on the received CQI report and the QoS request, and the CQI report The change instruction to is transmitted to the communication terminal. As a result, the base station 1 can change the format of the CQI report used by all communication terminals according to the number of communication terminals under its control, and unnecessarily uplink radio resources while satisfying the QoS request. Consumption will not increase. Also, the scheduling load of the base station can be adjusted according to the number of communication terminals under its control.

  Further, in the present embodiment, when the CQI report includes the average radio quality of all frequency bands and the average radio quality of at least one subband, the scheduler 21 has an average quality of all frequency bands and at least 1 Scheduling is performed according to the difference between the average radio quality of two subbands. As a result, transmission data can be efficiently allocated to a small number of radio resources, and the user accommodation rate can be improved.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions included in each unit, each step, etc. can be rearranged so that there is no logical contradiction, and a plurality of components, steps, etc. can be combined or divided into one. .

DESCRIPTION OF SYMBOLS 1 Communication terminal 10 Reception part 20 Control part 21 Scheduler 22 CQI report determination part 30 Transmission part

Claims (3)

A base station compatible with the OFDM system,
A receiving unit for receiving channel quality information and a QoS request from a communication terminal under its own station;
A scheduler for scheduling transmission data and subbands to each communication terminal based on the channel quality information and the QoS request;
A determination unit that determines a channel quality information format that satisfies a QoS request of a communication terminal under its own station based on the channel quality information and the QoS request;
A transmission unit that transmits a change instruction to the channel quality information format to a communication terminal under its own station,
A base station comprising: The base station according to claim 1, wherein
The scheduler, when the channel quality information includes an average radio quality of all frequency bands and an average radio quality of at least one subband,
Scheduling according to a difference between an average quality of the entire frequency band and an average radio quality of the at least one subband;
A base station characterized by that. A base station control method corresponding to an OFDM system,
Receiving channel quality information and a QoS request from a communication terminal under its control;
Scheduling transmission data and subbands to each communication terminal based on the channel quality information and the QoS request;
Determining, based on the channel quality information and the QoS request, a channel quality information format that satisfies a QoS request of a communication terminal under its own station;
Transmitting a change instruction to the channel quality information format to a communication terminal under its own station;
The control method characterized by including.

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