JP6833943B2 - system - Google Patents

Description

The present invention relates to a system.

The progress of technology (mobile wireless data communication technology) in which user terminals represented by mobile phone terminals perform data communication while moving is remarkable, and various wireless communication methods have been innovated and put into practical use. In recent years, the speed of 4th generation data communication such as LTE (Long Term Evolution) method or WiMAX (Worldwide Interoperability for Microwave Access) method using Orthogonal Frequency Division Multiple Access (OFDMA) technology has been accelerated. Communication standards are the mainstream.

On the other hand, the communication method of wireless LAN (Local Area Network), which has been mainly installed in personal computers (PCs), is a base station device using the CSMA / CA (Carrier Sense Multiple Access with Collision Avoidance) method. It has been developed based on the communication procedure of. The IEEE 802.11 Working Committee, which has established standards for wireless LAN communication methods, has established wireless LAN communication based on the current CSMA / CA in order to realize more efficient data communication. We are beginning to consider applying 802.11 technology to the scheme.

When applying the OFDMA technology to a wireless LAN, a Time Division Duplex (TDD) type OFDMA system such as WiMAX that transmits and receives at different timings on the same frequency channel is helpful.
In the case of WiMAX, it is operated in an environment where there is no wireless system that causes radio wave interference in addition to the system operated by one telecommunications carrier. Therefore, in the general frame configuration in the case of WiMAX, a downlink data frame for transmitting data in the direction from the base station device to the terminal device and an uplink data frame for transmitting data in the direction from the terminal device to the base station device are transmitted. Data frames in the direction are transmitted and received with a fixed frame length, a fixed number of subchannels, and a fixed transmission cycle, respectively.

U.S. Pat. No. 8,40968

However, since the wireless LAN system employs an access procedure based on CSMA / CA, the available wireless bandwidth changes dynamically, and the time length of the transmission frame changes the data size and wireless modulation rate. It has the characteristic that it fluctuates depending on the situation. Therefore, it is appropriate to consider the dynamically changing available radio bandwidth, the subcarrier used for OFDMA multiplexing, the size of data transmitted to each destination (each terminal device), the modulation rate used, and the like. There is a problem that the data length must be complemented so that the frame of OFDMA is constructed.

The technique described in Patent Document 1 is adopted in the IEEE802.11ac standard of wireless LAN, and is a frame directed to each terminal device when simultaneously transmitting data addressed to a plurality of terminal devices by spatial multiplexing or the like. Provided is a method of aligning the lengths of the above (see Patent Document 1). For example, as shown in FIG. 4 of Patent Document 1, data complementation (PHY PAD) in the physical layer and data complementation (MAC Padding) in the MAC (Media Access Control) layer are used in combination, which is inefficient. It was.

The present invention has been made in view of such circumstances, and aims to provide a system capable of performing efficient data interpolation when transmitting data to a plurality of terminal devices in a wireless communication device To do.

In order to solve the above problems, the system according to one aspect receives a wireless communication device that transmits data to a plurality of terminal devices at the same time timing and the data transmitted from the wireless communication device. In a system including the plurality of terminal devices, the wireless communication device is assigned to each terminal device of the plurality of terminal devices to which a plurality of subcarriers are distributed and assigned for transmission to the respective terminal devices. The number of subcarriers and the number of time slots assigned to each terminal device for transmission are obtained, and the number of subcarriers assigned to each terminal device, the bit length of data to be transmitted to each terminal device, and the plurality thereof. Based on the maximum value of the number of time slots assigned to each of the terminal devices, the complement amount calculation unit that calculates the amount of data to complement the data to be transmitted to each terminal device by the number of bits, and each terminal device , The complement unit that complements the data to be transmitted with the data of the amount of data calculated by the complement amount calculation unit, and the data complemented by the complement unit for the plurality of terminal devices using the plurality of subcarriers. It is a system including a transmission unit for transmitting data.

According to the present invention, data complementation can be efficiently performed when data is transmitted to a plurality of terminal devices.

It is a block diagram which shows the schematic structure of the base station apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the procedure of the processing of data complementation performed in the base station apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the result of carrier sense for a plurality of subchannels. It is a figure which shows the image of an example of the frame which was complemented before performing OFDMA modulation. (A) is a diagram showing an example of the time required for data transmission according to a comparative example, and (B) is a diagram showing an example of the time required for data transmission according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a schematic configuration of a base station apparatus 1 according to an embodiment of the present invention.
In the present embodiment, the base station device 1 is an access point (AP) device in a wireless LAN system. The base station device 1 may communicate data (for example, user data) with a plurality of terminal devices (not shown). The base station device 1 multiplexes data for a plurality of terminal devices by OFDMA and simultaneously transmits the data.

The base station apparatus 1 includes a plurality of data frame buffer units 11-1 to 11-N (N: N is an integer of 2 or more), a bit complement amount calculation unit 12, and a plurality of (N) bit complement units 13. It includes -1 to 13-N, an OFDMA frame generation unit 14, a wireless transmission / reception unit 15, a memory unit 16, a central control unit 17, and an antenna 21.
The base station device 1 includes, for example, other components necessary for use in a wireless LAN system, but detailed description thereof will be omitted.

In the present embodiment, the number of data frame buffer units 11-1 to 11-N and the number of bit complement units 13-1 to 13-N are the same (N), and they correspond to each other on a one-to-one basis. There is. In the present embodiment, one data frame buffer unit and one bit complement unit corresponding to the data frame buffer unit correspond to one terminal device. The N data frame buffer units 11-1 to 11-N and the N bit complement units 13-1 to 13-N make it possible to support up to N terminal devices.

Each data frame buffer unit 11-1 to 11-N temporarily stores data (transmission data) to be transmitted to each destination terminal device.
The bit complement amount calculation unit 12 calculates and obtains the data complement amount for the data (transmission data) to be transmitted to each destination terminal device. In the present embodiment, the complement amount of bit data is used as the complement amount of data.
Each bit completion unit 13-1 to 13-N is the data calculated by the bit completion amount calculation unit 12 for the transmission data temporarily stored in each data frame buffer unit 11-1 to 11-N. Data is complemented by the amount of complementation.

The OFDMA frame generation unit 14 generates an OFDMA frame using the transmission data whose data has been complemented by the bit complementation units 13-1 to 13-N. The frame may include transmission data for a plurality of terminal devices.
The wireless transmission / reception unit 15 wirelessly modulates the frame generated by the OFDMA frame generation unit 14 and transmits the frame via the antenna 21.
The radio transmitter / receiver 15 receives ambient radio waves via the antenna 21 to identify available radio subchannels. In the present embodiment, the specific method and identification criteria for identifying the available wireless subchannels follow the methods and criteria defined by the wireless system to be used.
The antenna 21 converts an electric signal (high frequency signal to be transmitted) input from the wireless transmission / reception unit 15 into radio waves and transmits the electric signal. The antenna 21 converts the received radio wave into an electric signal (received high-frequency signal) and outputs it to the wireless transmission / reception unit 15.

The memory unit 16 has a storage device and stores various types of information. The memory unit 16 may have a storage device that temporarily stores information, or may have a storage device that stores information non-temporarily.
The central control unit 17 controls various processes performed in the base station apparatus 1.

FIG. 2 is a diagram showing an example of a procedure of data complement processing performed in the base station apparatus 1 according to the embodiment of the present invention.
The processes of (step S1) to (step S4) performed in the base station apparatus 1 will be described. The process of (step S3) includes (step S11) to (step S13).

(Step S1)
First, the central control unit 17 outputs a carrier sense instruction to the wireless transmission / reception unit 15. When the carrier sense instruction is input from the central control unit 17, the wireless transmission / reception unit 15 executes the carrier sense process on the candidate wireless channel to be used, and outputs the result to the central control unit 17. The central control unit 17 determines the number of available subcarriers based on the result of carrier sense processing input from the wireless transmission / reception unit 15.
Here, the subcarrier is a plurality of subcarriers constituting the subchannel. Since the subcarriers are orthogonal to each other, they do not interfere with each other even if they are arranged next to each other on the frequency axis.

As a specific example, the wireless transmission / reception unit 15 receives ambient radio waves via the antenna 21 as a carrier sense process to identify unused and available subchannels. Then, the wireless transmission / reception unit 15 outputs the identification result of the available sub-channel to the central control unit 17 as a result of the carrier sense processing and notifies the central control unit 17.

FIG. 3 is a diagram showing an example of the result of carrier sense for a plurality of subchannels. In FIG. 3, the horizontal axis represents time and the vertical axis represents frequency.
In the example of FIG. 3, four subchannels (subchannels 1 to 4), each having a width of 20 MHz, are shown. The wireless transmission / reception unit 15 performs carrier sense in a band having a width of 80 MHz. Then, as a result of receiving the surrounding radio waves via the antenna 21, the wireless transmission / reception unit 15 identifies (determines) that the subchannels 3 and 4 are being used (in use) by another wireless device. , Subchannels 1 and 2 identify (determine) that they are not being used (available) by other wireless devices.

Here, in the present embodiment, the available subchannels are identified based on the reception status on the side of the base station apparatus 1, but as another configuration example, the destination is the destination for transmitting the OFDMA frame from the base station apparatus 1. Available subchannels may be identified based on the subchannels available (or unavailable) on the side of each terminal device. In this case, for example, each terminal device transmits information identifying a subchannel that is available (or unavailable) in its own device (each terminal device) to the base station device 1. The base station apparatus 1 receives the information and identifies available subchannels based on the information.
As a standard for identifying whether or not each subchannel is available, in the present embodiment, any standard may be used according to the provisions of the wireless LAN standard.

_{The central control unit 17 determines the number of available subcarriers SC total} (SC _total is an integer of 1 or more) based on the identification result of the available subchannels input from the radio transmission / reception unit 15.
The number of available subcarriers is determined by the available subchannels and their arrangement, and the determination method differs depending on the wireless communication method used.
In the example of FIG. 3, the central control unit 17 determines the number of subcarriers included in the available subchannels 1 and 2 as _{the number SC total of available subcarriers.}

(Step S2)
Each data frame buffer unit 11-1 to 11-N receives a MAC frame (in this embodiment, a MAC frame of a wireless LAN) which is data to be transmitted to each destination terminal device from a subsequent device, and temporarily receives the MAC frame. Keep it. Each data frame buffer unit 11-1 to 11-N is identified by the size of the transmission destination (destination) and a transmission data Addressing to each terminal device (temporarily Tomeoi data) (data length b _i) Get that information. i (i is an integer of 1 or more) represents the i-th destination terminal device. Each data frame buffer unit 11-1 to 11-N notifies and outputs the information of the data length b _i to be transmitted to the destination and the destination to the central control unit 17.
Here, the latter device is, for example, an Internet interface device connected to the base station device 1. The MAC frame, which is the data to be transmitted to each terminal device, is input to the base station device 1 from the subsequent device.

In the present embodiment, the header (frame header) of the MAC frame includes information on the address of the destination terminal device. Then, the MAC frame is retained by different data frame buffer units 11-1 to 11-N for each information of the destination address included in the header of the MAC frame. That is, in the present embodiment, N buffers (data frame buffer units 11-1 to 11-N) are prepared so as to correspond to N different addresses, and up to N different destinations (addresses) are provided. Correspondingly, MAC frames of a plurality of destinations are temporarily stored in a buffer (data frame buffer unit 11-1 to 11-N).
In the present embodiment, a wireless LAN standard MAC frame is used as the data frame, but as another configuration example, an aggregation frame in which MAC frames are connected may be used, or both of them are mixed. Those may be used.

(Step S3)
The central control unit 17, by receiving a notification from the data frame buffer unit 11-1 to 11-N, to obtain the address and data length information b _i of the transmission data for each destination of data in Tomeoki.
In the present embodiment, information on the modulation degree ml _i and the coding rate (coding rate) cr _i of the data to be used for wireless transmission is stored in the memory unit 16 for each destination terminal device. The central control unit 17 refers to the information stored in the memory unit 16 and reads it out. Then, the central control unit 17, the information of the number SC _total outputs the bit complementary quantity calculation unit 12 of the determined available subcarriers for each terminal device as a destination, the data length of the transmission data b _i, Information on the degree of modulation ml _i and the coding rate cr _i of the data to be used is output to the bit complement amount calculation unit 12. Some or all of this information may be treated as a set of information. As an example, information about each destination (for each terminal device of the i-th destination) may be treated as a set of information. The central control unit 17 outputs an instruction for calculating the bit complement amount to the bit complement amount calculation unit 12.
The values of the modulation degree ml _i and the coding rate cr _i of the data to be used are determined by, for example, the quality of the immediately preceding communication, but any method may be used as the determination method of these values. Good.

When the bit complement amount calculation unit 12 receives an instruction for calculating the bit complement amount from the central control unit 17, the bit complement amount calculation unit 12 transmits a frame for each destination terminal device based on the information input from the central control unit 17. The bit complement amount bpad _i for is calculated and obtained. The bit complementing amount calculating section 12 outputs the information bits complementing amount BPAD _i calculated for each terminal device as a destination, the bit complementation unit 13-1 to 13-N corresponding to each terminal device becomes the destination And notify.

(Step S4)
Each bit complement unit 13-1 to 13-N is for a data string of a MAC frame directed to each destination terminal device based on the information of _{the bit complement amount bpad i notified from the bit complement amount calculation unit 12.} , Bit complementation amount Complements by adding data with the number of bits corresponding to _{bpad i.} In the present embodiment, as a data complementing method, EOF (End Of Frame) data, which is a bit string indicating the end of a frame, is used as data of the number of bits corresponding _{to the bit complementing amount bpad i.} That is, in the present embodiment, the frame is filled (padded) with the EOF data. When the terminal device identifies the EOF, it determines that it is not necessary to analyze subsequent data bits. In addition, as a method of data complementation, another method may be used.

The OFDMA frame generation unit 14 uses the values _{of the predetermined modulation degree ml i} and the coding rate cr _i for the frame after data completion for each terminal device received from each bit complement unit 13-1 to 13-N. Modulate. Then, the OFDMA frame generation unit 14 superimposes the modulated data for each terminal device on the number _{of subcarriers (SC i} ) assigned to each terminal device to generate an OFDMA frame. The OFDMA frame generation unit 14 outputs the generated OFDMA frame to the wireless transmission / reception unit 15. The frame is OFDMA-multiplexed after adjusting the length of the data frame addressed to each terminal device by complementation, and these data frames are transmitted at the same time.
Here, the information on the number of subcarriers (SC _i ), the degree of modulation ml _i, and the coding rate cr _i assigned to each terminal device is an OFDMA frame from the bit complement amount calculation unit 12 or the central control unit 17, respectively. It is output to the generation unit 14 and notified. As an example, all of this information may be notified from the bit complement amount calculation unit 12 to the OFDMA frame generation unit 14. As another example, information on the number of subcarriers (SC _i ) is notified from the bit complement amount calculation unit 12 to the OFDMA frame generation unit 14, _{and information on the degree of modulation ml i} and the coding rate cr _i is transmitted to the central control unit 17. May be notified to the OFDMA frame generation unit 14. The wireless transmission / reception unit 15 wirelessly modulates the OFDMA frame input from the OFDMA frame generation unit 14 and transmits the OFDMA frame to the wireless space via the antenna 21. The central control unit 17 controls the timing of the transmission by outputting the transmission instruction to the wireless transmission / reception unit 15. In the present embodiment, the timing of the instruction is in accordance with the provisions of the wireless LAN, but any timing may be used.

Next, the processes of (step S11) to (step S13), which are the detailed processes performed in the above (step S3), will be described. This process is a process in which the bit complement amount calculation unit 12 calculates and obtains the _{bit complement amount bpad i.}

(Step S11)
The bit complement amount calculation unit 12 calculates and obtains _{the number SC i} of the subcarriers used when transmitting data to each destination terminal device. It is assumed that the total number of terminal devices to be transmitted at the same time is N.
First, the bit complement amount calculation unit 12 is assigned to each destination terminal device when superimposing _{data addressed to N terminal devices on SC total (number of available subcarriers) subcarriers.} The number of subcarriers SC _i'is calculated by Eq. (1).
In equation (1), the modulation degree ml _i, coding rate cr _i, the data length _{b i} of the transmission data, the number _{SC total} available subcarriers are used.

The remaining number SC _rest of the available subcarriers is calculated and calculated by Eq. (2).

Then, bit complement amount calculating section 12, until the remaining number _{SC rest} of the available subcarriers is zero (0), for each terminal device _{{(b i × cr i)} / (ml i × SC i ')} value obtained by calculation of the value of SC i of the terminal device having the maximum of all the _terminals' and updates the SC _i' by adding 1 to the 1 from SC _rest Performs subtraction processing. Here, when the values are the same for two or more terminal devices, the bit complement amount calculation unit 12 uses any one of the terminal devices in a preset order or a random order. select.
Thus, for each terminal device, _'obtained, the bit complementary amount calculating section 12, the value SC _i' number SC i of subcarriers assigned to determine the as SC _i. Here, SC _i is the number of subcarriers assigned and used when transmitting data to the i-th terminal device. In this way, a plurality of subcarriers are distributed and assigned to a plurality of terminal devices, and the number of subcarriers assigned to each terminal device can vary.

(Step S12)
The bit complement amount calculation unit 12 calculates and obtains _{the number SL i} of the required time slots for the OFDM time slots.
First, bit complement amount calculating section 12, by the equation (3), based on the coding rate cr _i, the data length b _i of the transmission data, the data length after encoding (in this embodiment, bit length) b Calculate and obtain _i-After.

Next, the bit complement amount calculation unit 12 uses the equation (4) to determine the number of OFDM time slots required to transmit the _{encoded data length bi-After data for each terminal device (required).} Number of time slots) Calculate _{SL i.} In equation (4), roundup represents an operation that rounds up the number of digits of a numerical value to the ones digit. The bit complement amount calculation unit 12 sets SL _{max as the SL i at which the required number of time slots SL i} is the maximum value among all the terminal devices.

(Step S13)
The bit complement amount calculation unit 12 calculates and obtains the bit complement amount (number of bits) bpad _{i required to fill the determined number SC i of} subcarriers and the number SL _{i of the required time slots.}
First, the bit complement amount calculation unit 12 has a data length (number of bits in this embodiment) Pad that is insufficient when _{(SC i} × SL _max × ml _i ) is _{filled with bi-After according to the equation (5).} Calculate and obtain _i-Before.

Next, the bit complement amount calculation unit 12 calculates and obtains the required bit complement amount bpad _{i by multiplying the calculated data length Pad i-Before} by the coding rate cr _{i according to the equation (6).}

FIG. 4 is a diagram showing an image of an example of frames complemented before performing OFDMA modulation.
In the example of FIG. 4, the number of available subcarriers SC _total is 18, and the number N of destination terminal devices is 4. Then, SC ₁ (= 5) subcarriers are assigned to the first terminal device, SC ₂ (= 3) subcarriers are assigned to the second terminal device, and SC _{3 is assigned to the third terminal device.} (= 7) subcarriers are assigned, and SC ₄ (= 3) subcarriers are assigned to the fourth terminal device. Further, the required number of time slots SL _max is 10.
As shown in FIG. 4, transmission data for each terminal device is arranged in each subcarrier in the direction of a predetermined data string, and predetermined bit data is filled in a portion where the data is insufficient. FIG. 4 shows a portion (padding portions 111 to 114) filled with the predetermined bit data.
Here, in the example of FIG. 4, one rectangle represents one subcarrier symbol (OFDM symbol). In this example, padding portions 111 to 114 adjusted in bit units smaller than one symbol are provided.

An example of the effect obtained in the base station apparatus 1 according to the present embodiment is shown with reference to FIGS. 5 (A) and 5 (B). However, in the examples of FIGS. 5A and 5B, the procedure for exchanging the acknowledgment signal (ACK) for confirming that the data has been normally received on the terminal device side is not considered and is omitted. To do.

FIG. 5A is a diagram showing an example of the time required for data transmission according to the comparative example. This comparative example is an example of the conventional technique.
In the conventional wireless LAN system, data cannot be transmitted to a plurality of terminal devices at the same time unless the spatial multiplexing technology of MU-MIMO (Multi User-Multi Input Multi Output) is used. Further, in the conventional wireless LAN system, since access control is performed by the CSMA / CA system, the time for competing adjustment between the carrier sense and other wireless devices exists as an overhead, and data is transmitted to a plurality of terminal devices. In some cases, the time to wait for transmission to other terminal devices had a large effect.

As a specific example, the example of FIG. 5A will be described.
The competition adjustment time (IFS: Inter Frame Space) between frames is 50 microseconds on average, and the time length of frames transmitted to each terminal device is 50 microseconds on average. It is assumed that the total number of terminal devices is eight. In this case, it takes 800 microseconds as a total time to complete the data transmission to all eight terminal devices. In FIG. 5A, To1 to To8 represent frames transmitted to the first terminal device to the eighth terminal device, respectively.

FIG. 5B is a diagram showing an example of the time required for data transmission according to the embodiment of the present invention.
The competition adjustment time (IFS) between frames is 50 microseconds on average, and the time length of frames transmitted to each terminal device is 250 microseconds on average. It is assumed that the total number of terminal devices is eight. In this case, it takes 300 microseconds as a total time to complete the data transmission to all eight terminal devices. In FIG. 5B, To1 to To8 represent frames transmitted to the first terminal device to the eighth terminal device, respectively.
As described above, in the present embodiment, data transmission can be made more efficient.

As described above, in the base station apparatus 1 according to the present embodiment, the data length can be adjusted by performing the data complementation necessary for transmitting the OFDMA frame. Therefore, in the base station device 1 according to the present embodiment, for example, even if the usable bandwidth, the number of terminal devices to be transmitted, or the size (data length) of the transmission data dynamically changes, a plurality of them. It is possible to multiplex the data for the terminal device of the above in the same OFDMA frame and transmit them at the same time. Further, in the base station apparatus 1 according to the present embodiment, for example, data complementation can be performed only by the physical layer (PHY layer), and in this case, data complementation can be performed by both the physical layer and the MAC layer. In comparison, communication efficiency is improved.
As described above, according to the base station device 1 according to the present embodiment, data complementation can be efficiently performed when data is transmitted to a plurality of terminal devices.

As a configuration example, the wireless communication device (base station device 1 in this embodiment) is a wireless communication device that transmits data to a plurality of terminal devices at the same time timing, and is distributed by a plurality of subcarriers. Complementary amount calculation unit (in the present embodiment, the bit complementary amount) for calculating the amount of data that complements the data to be transmitted (bit complementary amount in the present embodiment) for each terminal device of the plurality of terminal devices assigned in The calculation unit 12) and the complement unit that complements the data transmitted by the data amount calculated by the complement amount calculation unit for each terminal device (bit complement units 13-1 to 13-N in this embodiment). And a transmission unit (in the present embodiment, a transmission function unit of the wireless transmission / reception unit 15) that transmits data complemented by the complement unit for a plurality of terminal devices using a plurality of subcarriers.

As a configuration example, the wireless communication device includes a frame generation unit (in this embodiment, the OFDMA frame generation unit 14) that generates a frame in which data complemented by the complement unit is multiplexed and transmitted for a plurality of terminal devices.
As a configuration example, in the wireless communication device, the complement unit uses data of a bit string (EOF in this embodiment) indicating the end of the frame as the data to be complemented.
As a configuration example, in a wireless communication device, a MAC frame, a connected MAC frame, or both of them are used as a frame.
As a configuration example, in a wireless communication device, the complement amount calculation unit has at least the number of available (available) subcarriers, the size of data (data length) for each terminal device, and the degree of data modulation for each terminal device. , Calculate the amount of data to be complemented based on the data encoding rate for each terminal device.
As a configuration example, the wireless communication device includes a control unit (in this embodiment, a central control unit 17) that performs carrier sense processing to determine the number of usable subcarriers. In the present embodiment, carrier sense processing is performed to identify available subchannels, and the usable subcarriers are determined based on the result. As another configuration example, carrier sense processing is performed. , The available subcarriers may be identified and determined.
As a configuration example, the OFDMA method is used in the wireless communication device.
As a configuration example, the wireless communication device is an access point device of a wireless LAN system.

As a configuration example, in the wireless communication method, the amount of data that complements the data to be transmitted is calculated for each terminal device of a plurality of terminal devices distributed and assigned by a plurality of subcarriers, and the calculation is performed for each terminal device. The data to be transmitted is complemented by the data of the obtained data amount, and the complemented data for a plurality of terminal devices is transmitted at the same time timing by using a plurality of subcarriers.
As a configuration example, the program includes a step of calculating the amount of data that complements the data to be transmitted for each terminal device of a plurality of terminal devices distributed and assigned by a plurality of subcarriers, and a calculation for each terminal device. To make the computer execute a step of complementing the data to be transmitted with the data of the obtained data amount and a step of transmitting the complemented data for a plurality of terminal devices at the same time timing by using a plurality of subcarriers. It is a program of.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design changes and the like within a range not deviating from the gist of the present invention are also included.

Further, a program for realizing the functions of each device (for example, base station device 1) according to the above-described embodiment is recorded (stored) on a computer-readable recording medium (storage medium), and the recording medium is recorded (stored). The processing may be performed by loading the program recorded in the computer system into a computer system and executing the program.
The term "computer system" as used herein may include hardware such as an operating system (OS: Operating System) or peripheral devices.
The "computer-readable recording medium" includes flexible disks, optomagnetic disks, ROMs (Read Only Memory), writable non-volatile memories such as flash memories, and portable media such as DVDs (Digital Versatile Disks). A storage device such as a hard disk built into a computer system.
Further, the "computer-readable recording medium" is a volatile memory (for example, DRAM (for example, DRAM) inside a computer system that serves as a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. It shall include those that hold the program for a certain period of time, such as Dynamic Random Access Memory)). Further, the above program may be transmitted from a computer system in which this program is stored in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting a program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
Further, the above program may be for realizing a part of the above-mentioned functions. Further, the above program may be a so-called difference file (difference program) that can realize the above-mentioned functions in combination with a program already recorded in the computer system.

1 ... Base station device, 11-1 to 11-N ... Data frame buffer unit, 12 ... Bit complement amount calculation unit, 13-1 to 13-N ... Bit complement unit, 14 ... OFDMA frame generator, 15 ... Wireless transmission / reception Unit, 16 ... Memory unit, 17 ... Central control unit, 21 ... Antenna, 111-114 ... Padding unit

Claims (1)

In a system including a wireless communication device that transmits data to a plurality of terminal devices at the same time timing and the plurality of terminal devices that receive the data transmitted from the wireless communication device.
The wireless communication device is
The number of subcarriers assigned to transmission to each terminal device and the number of time slots assigned to transmission to each terminal device for each terminal device of the plurality of terminal devices to which a plurality of subcarriers are distributed and assigned. Based on the number of subcarriers assigned to each terminal device, the bit length of data transmitted to each terminal device, and the maximum number of time slots assigned to each of the plurality of terminal devices. , A complement amount calculation unit that calculates the amount of data that complements the data transmitted to each terminal device by the number of bits,
For each of the terminal devices, a complement unit that complements the data to be transmitted with the data of the data amount calculated by the complement amount calculation unit, and
A transmission unit that transmits data complemented by the complement unit for the plurality of terminal devices using the plurality of subcarriers, and a transmission unit.
To prepare
system.

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